US20200011405A1 - Ball type speed reducer - Google Patents
Ball type speed reducer Download PDFInfo
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- US20200011405A1 US20200011405A1 US16/482,472 US201816482472A US2020011405A1 US 20200011405 A1 US20200011405 A1 US 20200011405A1 US 201816482472 A US201816482472 A US 201816482472A US 2020011405 A1 US2020011405 A1 US 2020011405A1
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- rotating body
- output
- side rotating
- side face
- fixing member
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H25/00—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms
- F16H25/04—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms for conveying rotary motion
- F16H25/06—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms for conveying rotary motion with intermediate members guided along tracks on both rotary members
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H25/00—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms
- F16H25/04—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms for conveying rotary motion
- F16H25/06—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms for conveying rotary motion with intermediate members guided along tracks on both rotary members
- F16H2025/063—Gearings comprising primarily only cams, cam-followers and screw-and-nut mechanisms for conveying rotary motion with intermediate members guided along tracks on both rotary members the intermediate members being balls engaging on opposite cam discs
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H35/00—Gearings or mechanisms with other special functional features
- F16H2035/001—Gearings with eccentric mounted gears, e.g. for cyclically varying ratio
Definitions
- the present invention relates to a ball type speed reducer used for decelerating and transmitting rotation.
- a ball type speed reducer is used in a power transmission unit of various types of machines (such as an industrial robot or a steering angle variable type steering system) because it is small-sized and can obtain a larger reduction ratio, compared to a mechanical reduction gear.
- FIGS. 35A and 35B are diagrams illustrating the ball type speed reducer 100 of the prior art. Note that FIG. 35A is a longitudinal cross-sectional view illustrating the ball type speed reducer 100 of the prior art, and FIG. 35B is a cross-sectional view taken along the line A 18 -A 18 of FIG. 35A to illustrate the ball type speed reducer 100 .
- the ball type speed reducer 100 has an eccentric rotating plate 104 installed in an outer circumference side of an eccentric cam 102 provided in an input shaft 101 by interposing a bearing 103 , so that the eccentric rotating plate 104 is eccentrically driven by the eccentric cam 102 . Further, in this ball type speed reducer 100 , an output-side rotating body 105 coupled to an output shaft (not shown) is disposed in both inner sides of a radial direction of the eccentric rotating plate 104 , and the input shaft 101 is relatively turnably supported by an inner circumference side of the output-side rotating body 105 by interposing a bearing 106 .
- a fixing member 107 fixed to a part of an industrial robot or the like is disposed in both outer sides of the radial direction of the eccentric rotating plate 104 by interposing balls 108 , and the output-side rotating body 105 is turnably supported by the inner circumference side of the fixing member 107 by interposing a bearing 110 .
- the balls 108 interposed between the eccentric rotating plate 104 and the fixing member 107 are rollably engaged with a first corrugated groove (first cycloid groove formed in an epicycloid curve) 111 formed on a side face of the eccentric rotating plate 104 and a second corrugated groove (second cycloid groove formed in a hypocycloid curve) 112 formed on the inner side face (side face facing the eccentric rotating plate 104 ) of the fixing member 107 to connect the eccentric rotating plate 104 and the fixing member 107 .
- first corrugated groove first cycloid groove formed in an epicycloid curve
- second corrugated groove second cycloid groove formed in a hypocycloid curve
- the output-side rotating body 105 is connected to the eccentric rotating plate 104 by interposing an eccentricity absorption mechanism 113 .
- the eccentricity absorption mechanism 113 allows the eccentric rotating plate 104 to make an eccentric motion against the output-side rotating body 105 (to absorb eccentricity of the eccentric rotating plate 104 ) and transmits rotation of the eccentric rotating plate 104 to the output-side rotating body 105 .
- the eccentricity absorption mechanism 113 has a plurality of balls 114 interposed between the eccentric rotating plate 104 and the output-side rotating body 105 , a driving annular groove 115 of the eccentric rotating plate 104 that rollably houses the balls 114 , and a follower annular groove 116 of the output-side rotating body 105 .
- the driving annular groove 115 and the follower annular groove 116 have shapes and sizes determined by considering the eccentric amount of the eccentric cam 102 , and the eccentric rotating plate 104 allows a movement of the ball 114 for making eccentric rotation with respect to a rotation center of the input shaft 101 to turn the output-side rotating body 105 integrally with the eccentric rotating plate 104 by interposing the balls 114 (see Patent Document 1).
- the output-side rotating body 105 rotates by “ ⁇ 2/(N ⁇ 2)” for one rotation of the input shaft 101 (rotation by “2/(N ⁇ 2)” oppositely to the rotational direction of the input shaft 101 ). That is, the ball type speed reducer 100 of the prior art has a reduction ratio of “2/(N ⁇ 2)” when the number of waves of the first corrugated groove 111 of the eccentric rotating plate 104 is set to “N ⁇ 2,” and the number of waves of the second corrugated groove 112 of the fixing member 107 is set to “N.”
- Patent Document 1 Japanese Unexamined Patent Application Publication No. 5-10400
- the first corrugated groove 111 is formed in both side faces of the eccentric rotating plate 104
- the second corrugated groove 112 is formed on the inner side face of the fixing member 107 disposed in both sides of the eccentric rotating plate 104 . Therefore, it is necessary to form the corrugated grooves 111 , 111 , 112 and 112 in a total of four side faces (four places) with high accuracy, and this increases man-hours disadvantageously.
- the output-side rotating body 105 is connected to the eccentric rotating plate 104 by interposing the eccentricity absorption mechanism 113 . Therefore, it has a complicated structure, and increases man-hours disadvantageously.
- the present invention relates to a ball type speed reducer 1 that decelerates and transmits rotation of an input-side rotating body ( 2 , 3 ) to an output-side rotating body 8 .
- the ball type speed reducer 1 of the present invention includes: an eccentric disk cam 4 turning integrally with the input-side rotating body ( 2 , 3 ); a shaking body 5 fitted relatively turnably to an outer circumference side of the eccentric disk cam 4 and shaken by the eccentric disk cam 4 ; a plurality of balls 6 disposed along an outer circumferential surface 5 b of the shaking body 5 ; a fixing member 7 housing the shaking body 5 in an inner side of a radial direction such that the shaking body 5 is shakable and fixed to a fixation target member; a first output-side rotating body 8 A disposed to face one side face of the shaking body 5 and the fixing member 7 and relatively turnably supported by the input-side rotating body ( 2 , 3 ); and a second output-side rotating body 8 B disposed to face the other side face of the shaking body 5
- the outer circumferential surface 5 b of the shaking body 5 is a cylindrical surface concentric with a center 4 a of the eccentric disk cam 4 .
- the fixing member 7 has a plurality of radial grooves 38 as many as the balls 6 formed to slidably guide the balls 6 in the radial direction, and radial inner ends of the radial grooves 38 are open ends allowing the balls 6 to enter and exit.
- first output-side rotating body 8 A has a first side face portion 32 opposed to one side face of the fixing member 7 .
- the second output-side rotating body 8 B has a second side face portion 41 opposed to the other side face of the fixing member 7 .
- first side face portion 32 and the second side face portion 41 each have annular corrugated grooves 40 , 56 , 60 formed to spirally guide the balls 6 along the circumferential direction.
- the ball type speed reducer according to the present invention has the corrugated groove formed only in two places: at the first side face portions of the first output-side rotating body and the second side face portions of the second output-side rotating body, which face the shaking body and the fixing member. Therefore, it is possible to reduce the man-hours, compared to the prior art in which the corrugated groove is formed in each of four side faces. Further, the ball type speed reducer according to the present invention has the shaking body that can be shaken independently from the output-side rotating body (the first output-side rotating body and the second output-side rotating body) and the fixing member. Therefore, it is not necessary to provide a complicated mechanism for turning the output-side rotating body and the shaking body integrally. Accordingly, it is possible to simplify the structure and reduce the man-hours.
- FIG. 1 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a first embodiment of the invention.
- FIGS. 2A-2C are diagrams illustrating an input shaft (input-side rotating body) of a ball type speed reducer according to a first embodiment of the invention, in which FIG. 2A is a front view illustrating the input shaft (view illustrating a leading end face), FIG. 2B is a side view illustrating the input shaft, and FIG. 2C is a view illustrating a trailing end face of the input shaft.
- FIGS. 3A-3C are diagrams illustrating a cap (input-side rotating body) of the ball type speed reducer according to the first embodiment of the invention, in which FIG. 3A is a front view illustrating the cap, FIG. 3B is a cross-sectional view taken along the line A 1 -A 1 of FIG. 3A to illustrate the cap, and FIG. 3C is a rear view illustrating the cap.
- FIGS. 4A and 4B are diagrams illustrating a shaking body of the ball type speed reducer according to the first embodiment of the invention, in which FIG. 4A is a front view illustrating the shaking body, and FIG. 4B is a cross-sectional view taken along the line A 2 -A 2 of FIG. 4A to illustrate the shaking body.
- FIGS. 5A and 5B are diagrams illustrating a fixing member of the ball type speed reducer according to the first embodiment of the invention, in which FIG. 5A is a front view illustrating the fixing member, and FIG. 5B is a cross-sectional view taken along the line A 3 -A 3 of FIG. 5A to illustrate the fixing member.
- FIGS. 6A and 6B are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the first embodiment of the invention, in which FIG. 6A is a front view illustrating the first output-side rotating body, and FIG. 6B is a cross-sectional view taken along the line A 4 -A 4 of FIG. 6A to illustrate the first output-side rotating body.
- FIGS. 7A and 7B are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the first embodiment of the invention, in which FIG. 7A is a front view illustrating the second output-side rotating body, and FIG. 7B is a cross-sectional view taken along the line A 5 -A 5 of FIG. 7A to illustrate the second output-side rotating body.
- FIG. 8 is a perspective view illustrating a corrugated groove of the ball type speed reducer according to the first embodiment of the invention in a simplified manner.
- FIGS. 9A and 9B are diagrams illustrating a rolling trajectory of a ball when the ball is rolled in the corrugated groove, in which FIG. 9A is a plan view of the rolling trajectory of the ball, and FIG. 9B is a diagram illustrating waves whose rolling trajectory is projected on a virtual cross section taken along the line A 6 -A 6 of FIG. 9A .
- FIGS. 10A and 10B illustrate an explanatory diagram of a first modification of the corrugated groove in FIG. 10A , and an explanatory diagram of a second modification of the corrugated groove in FIG. 10B .
- FIG. 11 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a second embodiment of the invention.
- FIGS. 12A and 12B illustrate a front view of the first output-side rotating body in FIG. 12A , and a cross-sectional view taken along the line A 7 -A 7 of FIG. 12A to illustrate the first output-side rotating body in FIG. 12B .
- FIGS. 13A and 13B illustrate a front view of the second output-side rotating body in FIG. 13A , and a cross-sectional view taken along the line A 8 -A 8 of FIG. 13A to illustrate the second output-side rotating body in FIG. 13B .
- FIG. 14 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a third embodiment of the invention.
- FIG. 15 is a front view illustrating the ball type speed reducer according to the third embodiment of the invention in which a cap and a second output-side rotating body are removed.
- FIGS. 16A-16C are diagrams illustrating an input shaft (input-side rotating body) of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 16A is a front view illustrating the input shaft (view illustrating a leading end face), FIG. 16B is a side view illustrating the input shaft, and FIG. 16C is a cross-sectional view taken along the line A 9 -A 9 of FIG. 16A .
- FIGS. 17A-17C are diagrams illustrating a cap (input-side rotating body) of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 17A is a front view illustrating the cap, FIG. 17B is a side view illustrating the cap, and FIG. 17C is a cross-sectional view taken along the line A 10 -A 10 of FIG. 17A to illustrate the cap.
- FIGS. 18A and 18B are diagrams illustrating a shaking body of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 18A is a front view illustrating the shaking body, and FIG. 18A is a cross-sectional view taken along the line A 11 -A 11 of FIG. 18A to illustrate the shaking body.
- FIGS. 19A and 19B are diagrams illustrating a fixing member of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 19 A is a front view illustrating the fixing member, and FIG. 19B is a cross-sectional view taken along the line A 12 -A 12 of FIG. 19A to illustrate the fixing member.
- FIGS. 20A-20C are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 20A is a front view illustrating the first output-side rotating body, FIG. 20B is a side view illustrating the first output-side rotating body, and FIG. 20C is a cross-sectional view taken along the line A 13 -A 13 of FIG. 20A to illustrate the first output-side rotating body.
- FIGS. 21A-21C are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 21A is a front view illustrating the second output-side rotating body, FIG. 21B is a side view illustrating the second output-side rotating body, and FIG. 21C is a cross-sectional view taken along the line A 14 -A 14 of FIG. 21A to illustrate the second output-side rotating body.
- FIGS. 22A-22C are diagrams illustrating a rolling trajectory of a ball when the ball is rolled in a corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 22A is a plan view illustrating the rolling trajectory of the ball, FIG. 22B is a diagram illustrating waves whose rolling trajectory is projected on a virtual cross section taken along the line A 15 -A 15 of FIG. 22A , and FIG. 22C is an enlarged view illustrating the rolling trajectory of the ball of FIG. 22B .
- FIGS. 23A and 23B are diagrams illustrating a feature of the corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 23A illustrates an arrangement in which balls are located at the top in a rolling trajectory of the ball, and FIG. 23B is a cylindrical cross-sectional view taken at the position corresponding to the line A 16 -A 16 of FIG. 23B to illustrate the ball type speed reducer.
- FIGS. 24A and 24B are diagrams illustrating a feature of the corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 24A illustrates an arrangement in which balls are located at a middle position between the top and the bottom in a rolling trajectory of the ball, and FIG. 24B is a cylindrical cross-sectional view taken at the position corresponding to the line A 17 -A 17 of FIG. 24A to illustrate the ball type speed reducer.
- FIGS. 25A and 25B illustrate a diagram (corresponding to FIG. 22C ) illustrating a rolling trajectory of a ball according to a first modification of the third embodiment of the invention in FIG. 25A , and a diagram (corresponding to FIG. 22C ) illustrating a rolling trajectory of a ball according to a second modification of the third embodiment of the invention in FIG. 25A .
- FIGS. 26A and 26B are diagrams illustrating a ball type speed reducer according to a fourth embodiment of the invention, in which FIG. 26A is a front view illustrating the ball type speed reducer, and FIG. 26B is a side view illustrating the ball type speed reducer.
- FIG. 27 is a cross-sectional view taken along the line A 18 -A 18 of FIG. 26A to illustrate the ball type speed reducer.
- FIG. 28 is a front view illustrating the ball type speed reducer according to the fourth embodiment of the invention in which a cap and a second output-side rotating body are removed.
- FIGS. 29A-29D are diagrams illustrating an input shaft (input-side rotating body) of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 29A is a front view illustrating the input shaft (view illustrating a leading end face), FIG. 29B is a side view illustrating the input shaft, FIG. 29C is a rear view illustrating the input shaft (view illustrating a trailing end face), and FIG. 29D is a cross-sectional view taken along the line A 19 -A 19 of FIG. 29A .
- FIGS. 30A-30D are diagrams illustrating the cap (input-side rotating body) of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 30A is a front view illustrating the cap, FIG. 30B is a side view illustrating the cap, FIG. 30C is a rear view illustrating the cap, and FIG. 30D is a cross-sectional view taken along the line A 20 -A 20 of FIG. 30A to illustrate the cap.
- FIGS. 31A-31F are diagrams illustrating a modification of a shaking body of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 31A is a front view illustrating the shaking body, FIG. 31B is a side view illustrating the shaking body, FIG. 31C is a rear view illustrating the shaking body, FIG. 31D is a cross-sectional view taken along the line A 21 -A 21 of FIG. 31A to illustrate the shaking body, FIG. 31E is an enlarged view illustrating the section B 1 of FIG. 31B , and FIG. 31F is a diagram illustrating the shaking body engaging a ball.
- FIGS. 32A-32F are diagrams illustrating a fixing member of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 32A is a front view illustrating the fixing member, FIG. 32B is a side view illustrating the fixing member, FIG. 32C is a rear view illustrating the fixing member, FIG. 32D is a cross-sectional view taken along the line A 22 -A 22 of FIG. 32A to illustrate the fixing member, FIG. 32E is an enlarged view illustrating the section B 2 of FIG. 32A , and FIG. 32F is a cross-sectional view taken along the line A 23 -A 23 of FIG. 32E .
- FIGS. 33A-33D are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 33A is a front view illustrating the first output-side rotating body in which a corrugated groove is formed, FIG. 33B is a side view illustrating the first output-side rotating body, FIG. 33C is a cross-sectional view taken along the line A 24 -A 24 of FIG. 33A to illustrate the first output-side rotating body, and FIG. 33D is a rear view illustrating the first output-side rotating body.
- FIGS. 34A-34D are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the fourth embodiment of the invention, in which FIG. 34A is a front view illustrating the second output-side rotating body in which a corrugated groove is formed, FIG. 34B is a side view illustrating the second output-side rotating body, FIG. 34C is a cross-sectional view taken along the line A 25 -A 25 of FIG. 34A to illustrate the second output-side rotating body, and FIG. 34D is a rear view illustrating the second output-side rotating body.
- FIGS. 35A and 35B are diagrams illustrating a ball type speed reducer of the prior art, in which FIG. 35A is a longitudinal cross-sectional view illustrating the ball type speed reducer, and FIG. 35B is a cross-sectional view taken along the line A 26 -A 26 of FIG. 35A .
- FIG. 1 is a longitudinal cross-sectional view illustrating a ball type speed reducer 1 according to a first embodiment of the invention.
- the ball type speed reducer 1 according to this embodiment includes an input shaft (input-side rotating body) 2 , a cap (input-side rotating body) 3 , an eccentric disk cam 4 , a shaking body 5 , a plurality of balls (steel balls) 6 , a fixing member 7 , an output-side rotating body 8 (a first output-side rotating body 8 A and a second output-side rotating body 8 B), and the like.
- the input shaft 2 turnably supports the first output-side rotating body 8 A by interposing a first bearing 10 , so that the input shaft 2 is rotationally driven by a motor or the like (not shown).
- the input shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of a shaft body portion 11 is adjacent to the shaft body portion 11 .
- a bearing support portion 13 is formed adjacent to the flange-like portion 12 .
- the first bearing 10 is attached to the bearing support portion 13 to hold the first bearing 10 between an inner protrusion 15 of a bearing hole 14 of the first output-side rotating body 8 A and the flange-like portion 12 .
- the input shaft 2 has the eccentric disk cam 4 formed closer to a shaft tip side than the bearing support portion 13 and in the vicinity of the bearing support portion 13 .
- This eccentric disk cam 4 is a decentered shaft portion having a center 4 a decentered from a rotation center 2 a of the input shaft 2 (a rotation center 11 a of the shaft body portion 11 ) by an eccentric amount “e,” and is eccentrically rotated integrally with the input shaft 2 by virtue of rotation of the rotation center 2 a of the input shaft 2 .
- the shaking body 5 is relatively turnably installed in the outer circumference side of the eccentric disk cam 4 by interposing a second bearing 16 .
- the input shaft 2 has a tip shaft portion 17 formed to install the cap 3 .
- the tip shaft portion 17 has a rotation center concentric with the rotation center 2 a of the shaft body portion 2 and fitted in a shaft hole 18 of the cap 3 and has a leading end face 17 a abutting on a stopper protrusion 20 protruding into the shaft hole 18 of the cap 3 . Further, in the tip shaft portion 17 of the input shaft 2 , a screw hole (female screw) 22 to be screwed with a screw shaft portion 21 a of a bolt 21 for fixing the cap 3 is formed. Note that, in the following description, considering a virtual plane perpendicular to the rotation center 2 a of the input shaft 2 , it is assumed that a radial direction refers to a direction extending radially from the rotation center 2 a on the virtual plane.
- a circumferential direction refers to a direction along an outer edge of a virtual circle centered at the rotation center 2 a of the input shaft 2 .
- the cap 3 is fixed to the tip shaft portion 17 of the input shaft 2 with the bolt 21 , constitutes an input-side rotating body together with the input shaft 2 , and has a rotation center 3 a coinciding with the rotation center 2 a of the input shaft 2 .
- the cap 3 has the shaft hole 18 opened at one end side (right end side in FIG. 3B ) along the rotation center 3 a , a bolt head housing hole 23 opened at the other end side along the rotation center 3 a (left end side in FIG. 3B ), and a bolt shaft insertion hole 24 through which the bolt head housing hole 23 and the shaft hole 18 are communicated with each other.
- the cap 3 has a ring-shaped bearing stopper 25 on one end side of a cylindrical outer circumferential surface 3 b .
- a side face of a third bearing 26 attached to the outer circumferential surface 3 b abuts on the bearing stopper 25 , so that the third bearing 26 is held between an inner protrusion 28 in a bearing hole 27 of the second output-side rotating body 8 B and the bearing stopper 25 .
- the rotation center of the shaft hole 18 and the rotation center of the outer circumferential surface 3 b are concentric with the rotation center 3 a of the cap 3 .
- the shaking body 5 is formed in a disk shape so as to be shaken by the eccentric disk cam 4 , has a central bearing hole 30 fitted to the outer circumferential surface of the second bearing 16 , and is supported by the second bearing 16 so as to be able to turn relative to the eccentric disk cam 4 .
- a center 5 a is formed so as to be concentric with the center 4 a of the eccentric disk cam 4
- an outer circumferential surface 5 b is a cylindrical surface concentric with the center 4 a of the eccentric disk cam 4 .
- the plurality of balls 6 are rotatably supported at the outer circumferential surface 5 b .
- the shaking body 5 in the shaking body 5 , eight through holes 31 are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearing hole 30 .
- the through hole 31 of the shaking body 5 is engaged with a coupling protrusion 33 formed on a first side face portion 32 of the first output-side rotating body 8 A with a gap therebetween, and is formed to have a size such that the through hole 31 does not contact the coupling protrusion 33 even when the shaking body 5 is shaken by the eccentric disk cam 4 .
- the fixing member 7 has a substantially square shape on the front side, and a shaking body housing hole 34 is formed in its central portion.
- the fixing member 7 has a fixing frame portion 35 formed along the outer edge, and a radial groove forming disk portion 36 formed on the inner side of the radial direction of the fixing frame portion 35 .
- bolt holes 37 are formed at four corners of the fixing frame portion 35 . Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixing member 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts.
- the fixing member 7 is fixed to the fixation target member such that a center 34 a of the shaking body housing hole 34 is concentric with the rotation center 2 a of the input shaft 2 .
- the shaking body 5 is housed in the shaking body housing hole 34 of the fixing member 7 so as to be able to be shaken.
- a plurality of radial grooves 38 extending along the radial direction from an inner circumferential surface 34 b of the shaking body housing hole 34 are formed along the circumferential direction at equal intervals (in “(N+1)/3” places when the number of waves of a corrugated groove 40 is set to “N”).
- the radial groove 38 is an open end whose radial inner end allows the ball 6 to enter and exit, has a groove width slightly larger than the diameter of the ball 6 , and has a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (the eccentric amount e of the eccentric disk cam 4 ), so that the ball 6 supported at the outer circumferential surface 5 b of the shaking body 5 is slidably moved along the radial direction.
- a plate thickness of the radial groove forming disk portion 36 is formed smaller than the diameter of the ball 6 , so that the ball 6 is uniformly protruded on both sides of the radial groove forming disk portion 36 and the ball 6 in the radial groove 38 is rollably engaged with the corrugated groove 40 formed in the output-side rotating body 8 when the center of the ball 6 engaged with the radial groove 38 is aligned with the center position in the thickness direction of the radial groove forming disk portion 36 .
- Such radial grooves 30 of the fixing member 7 can roll the balls 6 in the radial direction depending on a shake amount of the shaking body 5 as the eccentric disk cam 4 rotates by one turn, and the shaking body 5 is shaken by one stroke.
- the plate thickness of the radial groove forming disk portion 36 of the fixing member 7 is the same as the plate thickness of the shaking body 5 .
- the first output-side rotating body 8 A has the first side face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shaking body 5 , and one side face 36 a of both side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 . Further, in the first output-side rotating body 8 A, the bearing hole 14 for housing the first bearing 10 attached to the input shaft 2 is formed, so that the side face of the outer race of the first bearing 10 abuts on the inner protrusion 15 formed at the end of the bearing hole 14 .
- a plurality of coupling protrusions 33 for coupling and fixing the second output-side rotating body 8 B are formed at equal intervals (in eight places) in the circumferential direction.
- the coupling protrusion 33 is inserted into the through hole 31 of the shaking body 5 so as to be fitted in a coupling protrusion housing recess 42 formed on a second side face portion 41 of the second output-side rotating body 8 B.
- a screw hole (female screw) 44 for fixing the second output-side rotating body 8 B with a bolt 43 is formed in the coupling protrusion 33 .
- a contact relief recess 45 is formed between the adjacent coupling protrusions 33 , 33 , and a lubricant such as grease is suitably contained in the contact relief recess 45 .
- the corrugated groove 40 is formed on the outer side of the radial direction of the coupling protrusion 33 and the contact relief recess 45 .
- the second output-side rotating body 8 B has the second side face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shaking body 5 , and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 .
- a plurality of the coupling protrusion housing recesses 42 in which the coupling protrusions 33 are fitted are formed as many as the coupling protrusions 33 at positions facing the respective coupling protrusions 33 of the first output-side rotating body 8 A.
- a contact relief recess 46 is formed between the adjacent coupling protrusion housing recesses 42 , 42 , and a lubricant such as grease is suitably contained in the contact relief recess 46 .
- the bearing hole 27 for housing the third bearing 26 attached to the cap 3 is formed, so that the side face of the outer race of the third bearing 26 abuts on the inner protrusion 28 formed at the end of the bearing hole 27 .
- a relief hole 47 for avoiding contact with the second bearing 16 is formed on the inner side of the radial direction on the second side face portion 41 side.
- the corrugated groove 40 is formed on the outer side of the radial direction of the coupling protrusion housing recess 42 and the contact relief recess 46 .
- a bolt head housing recess 50 opened at a side face 48 placed opposite to the second side face portion 41 is formed at a position facing the coupling protrusion 33 of the first output-side rotating body 8 A, and a bolt hole 51 through which the bolt head housing recess 50 and the coupling protrusion housing recess 42 are communicated with each other is formed.
- a screw shaft portion 43 a of the bolt 43 inserted into the bolt head housing recess 50 and the bolt hole 51 is screwed into the screw hole 44 of the coupling protrusion 33 of the first output-side rotating body 8 A, so that the second output-side rotating body 8 B is fixed to the first output-side rotating body 8 A, and is integrated with the first output-side rotating body 8 A to constitute the output-side rotating body 8 .
- a plurality of screw holes 52 are formed along the circumferential direction at a position radially inward of the bolt head housing recess 50 on the side face 48 opposite to the second side face portion 41 , so that a rotation target member (not shown) to be turned by the second output-side rotating body 8 B is fixed with a plurality of bolts (not shown) screwed into the plurality of screw holes 52 .
- the corrugated groove 40 is formed to have waves in which a portion located at a radial inner end of a wave is referred to as a bottom 40 a and a portion located at a radial outer end of the wave is referred to as a top 40 b , the bottom 40 a is formed across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B.
- the top 40 b of odd-numbered waves is formed to have a groove depth such that any one side of the first side face portion 32 and the second side face portion 41 is deeper than the other side of the first side face portion 32 and the second side face portion 41
- the top 40 b of even-numbered waves is formed to have a groove depth such that the other side of the first side face portion 32 and the second side face portion 41 is deeper than the one side of the first side face portion 32 and the second side face portion 41
- the groove depth is formed to gradually increase from the bottom 40 a toward the top 40 b . That is, the corrugated groove 40 has a shape similar to “offset teeth” of a saw blade.
- the ball 6 When moving along the radial direction in the radial groove 38 , the ball 6 , which is engaged with the corrugated groove 40 of the first output-side rotating body 8 A, the corrugated groove 40 of the second output-side rotating body 8 B, and also the radial groove 38 of the fixing member 7 , is also moved in the direction along the rotation center 2 a of the input shaft 2 by following the three-dimensionally formed corrugated groove 40 .
- the corrugated groove 40 is formed across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B as described above, the corrugated groove 40 is shaped with high precision without any deviation between the corrugated groove 40 on the first output-side rotating body 8 A side and the corrugated groove 40 on the second output-side rotating body 8 B side.
- FIGS. 9A and 9B are diagrams illustrating a rolling trajectory 55 of the ball 6 when the ball 6 is rolled in the corrugated groove 40 .
- FIG. 9A is a plan view illustrating the rolling trajectory 55 of the ball 6 (rolling trajectory 55 projected on a virtual plane perpendicular to the rotation center 2 a of the input shaft 2 ).
- FIG. 9B is a diagram illustrating waves W 1 and W 2 of adjacent rolling trajectories projected on a virtual cross section taken along the line A 6 -A 6 of FIG. 9A .
- the rolling trajectory 55 of the ball 6 shown in FIGS. 9A and 9B indicates a groove shape of the corrugated groove 40 .
- R represents the radial direction
- Z represents the direction along the rotation center 2 a of the input shaft 2 .
- the first wave W 1 of the waves W 1 and W 2 of the rolling trajectories 55 adjacent to each other is inclined from the bottom 40 a to the top 40 b of the corrugated groove 40 in the ⁇ Z direction at a constant rate.
- the second wave W 2 of the rolling trajectory 55 is inclined from the bottom 40 a to the top 40 b of the corrugated groove 40 in the +Z direction at a constant rate.
- the amount of movement of the first wave W 1 in the ⁇ Z direction is the same as the amount of movement of the second wave W 2 in the +Z direction.
- the corrugated groove 40 which forms the first wave W 1 of the rolling trajectory 55 is formed such that a portion corresponding to the top 40 b is deeper on the first side face portion 32 side of the first output-side rotating body 8 A.
- the corrugated groove 40 which forms the second wave W 2 of the rolling trajectory 55 is formed such that a portion corresponding to the top 40 b is deeper on the second side face portion 41 side of the second output-side rotating body 8 B.
- FIG. 10A is a diagram illustrating a first modification of the corrugated groove 40 , and corresponding to FIG. 9B .
- the first wave W 1 of the waves W 1 and W 2 of the rolling trajectories 55 adjacent to each other has a moving rate increased from the bottom 40 a to the top 40 b of the corrugated groove 40 in the ⁇ Z direction (as the ball 6 moves from radially inward to radially outward).
- the second wave W 2 of the rolling trajectory 55 has a moving rate increased from the bottom 40 a to the top 40 b of the corrugated groove 40 in the +Z direction (as the ball 6 moves from radially inward to radially outward).
- the corrugated groove 40 may be formed to have the rolling trajectory 55 of the ball 6 shown in FIG. 10A .
- FIG. 10B is a diagram illustrating a second modification of the corrugated groove 40 , and corresponding to FIG. 9B .
- the first wave W 1 of the waves W 1 and W 2 of the rolling trajectories 55 adjacent to each other has a moving rate decreased from the bottom 40 a to the top 40 b of the corrugated groove 40 in the ⁇ Z direction (as the ball 6 moves from radially inward to radially outward).
- the second wave W 2 of the rolling trajectory 55 has a moving rate decreased from the bottom 40 a to the top 40 b of the corrugated groove 40 in the +Z direction (as the ball 6 moves from radially inward to radially outward).
- the corrugated groove 40 may be formed to have the rolling trajectory 55 of the ball 6 shown in FIG. 10B .
- the shaking body 5 is shaken by a dimension “2e” twice the eccentric amount “e” of the eccentric disk cam 4 , so that the balls 6 supported at the outer circumferential surface 5 b of the shaking body 5 reciprocate inside the radial grooves 38 of the fixing member 7 by one trip.
- the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B) turns with respect to the fixing member 7 by one wave of the corrugated groove 40 because the balls 6 move in the radial direction of the first side face portion 32 and the second side face portion 41 inside the radial grooves 38 of the fixing member 7 . Therefore, in the ball type speed reducer 1 according to this embodiment, since the number of waves of the corrugated groove 40 is set to “N,” and the number of radial grooves 38 is set to “(N+1)/3,” the output-side rotating body 8 rotates by a “1/N” turn oppositely to the input shaft 2 while the input shaft 2 rotates by one turn. Note that, as illustrated in FIGS.
- the ball type speed reducer 1 decelerates rotation of the input shaft 2 by “ 1/50 (1/N)” and transmits the decelerated rotation to the output-side rotating body 8 .
- the corrugated grooves 40 are formed only in two places: the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B, which face the shaking body 5 and the fixing member 7 , it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (see FIGS. 35A and 35B ) in which the corrugated grooves 111 , 111 , 112 and 112 are formed in four places.
- the shaking body 5 can be shaken independently from the fixing member 7 and the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B). Therefore, it is not necessary to provide a complicated mechanism for rotating the shaking body 5 and the output-side rotating body 8 integrally (for example, the eccentricity absorption mechanism 113 , 113 of the ball type speed reducer 100 in the prior art shown in FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours.
- the ball 6 is positioned in a portion where the radial groove 38 and the corrugated groove 40 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which the balls 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentric rotating plate 104 and the groove wall of the second corrugated groove 112 of the fixing member 107 (see FIGS. 35A and 35B ), it is possible to facilitate machining of the radial groove 38 and the corrugated groove 40 and an assembly work for the shaking body 5 , the fixing member 7 , the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B), and the like.
- the corrugated groove 40 is formed to have an equal groove depth at the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B, the groove depth at the top 40 b of the corrugated groove 40 which contributes significantly to torque transmission is made deeper. Therefore, the amount of engagement between the top 40 b of the corrugated groove 40 including its vicinity and the ball 6 is increased, thereby making it possible to increase a transmittable torque.
- the number of radial grooves 38 is set to “(N+1)/3” and the number of balls 6 housed in the radial groove 38 is set to “(N+1)/3.” Therefore, it is possible to reduce the weight by the reduced number of balls 6 , compared to the case where the number of radial grooves 38 is set to “(N+1)” and the number of balls housed in the radial groove 38 is set to “(N+1).”
- the number of radial grooves 38 is set to “(N+1)/3” and the number of balls 6 housed in the radial groove 38 is set to “(N+1)/3.” Therefore, the size of the ball 6 can be set to be larger, and a large torque can be transmitted although the number of balls 6 is reduced.
- the ball type speed reducer 1 since a plurality of the contact relief recesses 45 and 46 for reducing a contact resistance by reducing a contact area with the shaking body 5 are provided in the first output-side rotating body 8 A and the second output-side rotating body 8 B, it is possible to effectively transmit power.
- the reduction ratio becomes “1/N.” Therefore, it is possible to increase the reduction ratio relative to the ball type speed reducer 100 of the prior art illustrated in FIG. 35 .
- the number “N” of waves of the corrugated groove 40 of the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B) is set to “50,” the number “(N+1)/3” of radial grooves 38 of the fixing member 7 is set to “17,” and the number of balls 5 is set to “17” by way of example.
- the number “N” of waves of the corrugated groove 40 , the number “(N+1)/3” of radial grooves 38 , and the number of balls 6 may be determined to change the reduction ratio on the conditions that the number “N” of waves of the corrugated groove 40 is set to an even number (a multiple of “2”) and the number “(N+1)/3” of radial grooves 38 is set to a natural number.
- the number of balls 6 may be smaller than the number of grooves of the radial groove 40 as long as smooth rotation transmission of the ball type speed reducer 1 is not impaired.
- the number “N” of waves of the corrugated groove 40 of the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B) is set to “50,” the number “(N+1)/3” of radial grooves 38 of the fixing member 7 is set to “17,” and the number of balls 6 is set to “17” by way of example.
- the number “N” of waves of the corrugated groove 40 , the number “(N ⁇ 1)/3” of radial grooves 38 , and the number of balls 6 may be determined to change the reduction ratio on the conditions that the number “N” of waves of the corrugated groove 40 is set to an even number (a multiple of “2”) and the number “(N ⁇ 1)/3” of radial grooves 38 is set to a natural number.
- their numbers may be determined such that the number “N” of waves of the corrugated groove 40 of the output-side rotating body 8 is set to “46,” the number “(N ⁇ 1)/3” of radial grooves 38 of the fixing member 7 is set to “15,” and the number “(N ⁇ 1)/3” of balls 6 is set to “15.”
- the output-side rotating body 8 rotates by “1/N” for one rotation of the input shaft 2 in the same rotation direction as the input shaft 2 .
- the number of balls 6 may be smaller than the number of radial grooves 38 as long as smooth rotation transmission of the ball type speed reducer 1 is not impaired.
- FIGS. 11-13B are explanatory diagrams of the ball type speed reducer 1 according to a second embodiment of the invention.
- FIG. 11 is a longitudinal cross-sectional view illustrating the ball type speed reducer 1 according to the second embodiment of the invention.
- FIG. 12A is a front view illustrating the first output-side rotating body 8 A
- FIG. 12B is a cross-sectional view taken along the line A 7 -A 7 of FIG. 12A to illustrate the first output-side rotating body 8 A.
- FIG. 13A is a front view illustrating the second output-side rotating body 8 B
- FIG. 13B is a cross-sectional view taken along the line A 8 -A 8 of FIG. 13A to illustrate the second output-side rotating body 8 B.
- the shape of corrugated grooves 56 of the first output-side rotating body 8 A and the second output-side rotating body 8 B are different from the shape of the corrugated grooves 40 of the first output-side rotating body 8 A and the second output-side rotating body 8 B in the ball type speed reducer 1 according to the first embodiment, but the other configuration is the same as the ball type speed reducer 1 according to the first embodiment. Therefore, in the description of the ball type speed reducer 1 according to this embodiment, like reference numerals denote like elements as in the ball type speed reducer 1 of the first embodiment, and they will not be repeatedly described.
- the corrugated groove 56 is formed across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B.
- a first corrugated groove portion 56 A on the first output-side rotating body 8 A side and a second corrugated groove portion 56 B on the second output-side rotating body 8 B side in the corrugated grooves 56 have the same planar shape and same groove depth, and has a shape such that one is mirrored to the other.
- first corrugated groove portion 56 A on the first output-side rotating body 8 A side and the second corrugated groove portion 56 B on the second output-side rotating body 8 B side are formed to have a constant groove depth, unlike the corrugated grooves 40 of the ball type speed reducer 1 according to the first embodiment.
- the number of waves of the corrugated groove 56 (the numbers of waves of the first corrugated groove portion 56 A of the first output-side rotating body 8 A and the second corrugated groove portion 56 B of the second output-side rotating body 8 B) is set to “50,” the number “(N+1)/3” of radial grooves 38 of the fixing member 7 is set to “17,” and the number of balls 6 is set to “17” by way of example.
- the ball type speed reducer 1 according to this embodiment is not limited to an even number “N” of waves of the corrugated groove 56 , and the number “N” of waves of the corrugated groove 56 may be set to an odd number, and the number of radial grooves 38 may be set to “N+1,” “N ⁇ 1,” “(N+1)/2,” or “(N ⁇ 1)/2.”
- the corrugated grooves 56 are formed only in two places: the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion of the second output-side rotating body 8 B (the first corrugated groove portion 56 A of the corrugated groove 56 is formed in the first side face portion 32 of the first output-side rotating body 8 A, and the second corrugated groove portion 56 B of the corrugated groove 56 is formed in the second side face portion 41 of the second output-side rotating body 8 B), it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (see FIGS.
- the shaking body 5 can be shaken independently from the fixing member 7 and the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B). Therefore, it is not necessary to provide a complicated mechanism for turning the shaking body 5 and the output-side rotating body 8 integrally (for example, the eccentricity absorption mechanism 113 , 113 of the ball type speed reducer 100 in the prior art shown in FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours.
- the ball 6 is positioned in a portion where the radial groove 38 and the corrugated groove 56 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which the balls 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentric rotating plate 104 and the groove wall of the second corrugated groove 112 of the fixing member 107 (see FIGS. 35A and 35B ), it is possible to facilitate machining of the radial groove 38 and the corrugated groove 56 and an assembly work for the shaking body 5 , the fixing member 7 , the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B), and the like.
- FIG. 14 is a longitudinal cross-sectional view illustrating a ball type speed reducer 1 according to a third embodiment of the invention.
- the ball type speed reducer 1 according to this embodiment includes an input shaft (input-side rotating body) 2 , a cap (input-side rotating body) 3 , an eccentric disk cam 4 , a shaking body 5 , a plurality of balls (steel balls) 6 , a fixing member 7 , an output-side rotating body 8 (a first output-side rotating body 8 A and a second output-side rotating body 8 B), and the like.
- FIG. 15 is a front view illustrating the ball type speed reducer 1 in which the cap 3 , the second output-side rotating body 8 B, the shaking body 5 , and the like are removed.
- the input shaft 2 turnably supports the first output-side rotating body 8 A by interposing a first bearing 10 , so that the input shaft 2 is rotationally driven by a motor or the like (not shown).
- the input shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of a shaft body portion 11 is adjacent to the shaft body portion 11 .
- a bearing support portion 13 is formed adjacent to the flange-like portion 12 .
- the first bearing 10 is attached to the bearing support portion 13 to hold the first bearing 10 between an inner protrusion 15 of a bearing hole 14 of the first output-side rotating body 8 A and the flange-like portion 12 .
- the input shaft 2 has the eccentric disk cam 4 formed closer to a shaft tip side than the bearing support portion 13 and in the vicinity of the bearing support portion 13 .
- This eccentric disk cam 4 is a decentered shaft portion having a center 4 a decentered from a rotation center 2 a of the input shaft 2 (a rotation center 11 a of the shaft body portion 11 ) by an eccentric amount “e,” and is eccentrically rotated integrally with the input shaft 2 by virtue of rotation of the rotation center 2 a of the input shaft 2 .
- the shaking body 5 is relatively turnably installed in the outer circumference side of the eccentric disk cam 4 by interposing a second bearing 16 .
- the input shaft 2 has a tip shaft portion 17 formed to install the cap 3 .
- the tip shaft portion 17 has a rotation center concentric with the rotation center 2 a of the shaft body portion 2 and fitted in a shaft hole 18 of the cap 3 and has a leading end face 17 a abutting on a stopper protrusion 20 protruding into the shaft hole 18 of the cap 3 . Further, in the tip shaft portion 17 of the input shaft 2 , a screw hole (female screw) 22 to be screwed with a screw shaft portion 21 a of a bolt 21 for fixing the cap 3 is formed.
- the cap 3 is fixed to the tip shaft portion 17 of the input shaft 2 with the bolt 21 , constitutes an input-side rotating body together with the input shaft 2 , and has a rotation center 3 a coinciding with the rotation center 2 a of the input shaft 2 .
- the cap 3 has the shaft hole 18 opened at one end side (right end side in FIG. 17C ) along a rotation center 3 a , a bolt head housing hole 23 opened at the other end side along the rotation center 3 a (left end side in FIG. 17C ), and a bolt shaft insertion hole 24 through which the bolt head housing hole 23 and the shaft hole 18 are communicated with each other.
- the cap 3 has a ring-shaped bearing stopper 25 on the left end side of a cylindrical outer circumferential surface 3 b .
- a side face of a third bearing 26 attached to the outer circumferential surface 3 b abuts on the bearing stopper 25 , so that the third bearing 26 is held between an inner protrusion 28 in the bearing hole 27 of the second output-side rotating body 8 B and the bearing stopper 25 .
- the rotation center of the shaft hole 18 and the rotation center of the outer circumferential surface 3 b are concentric with the rotation center 3 a of the cap 3 .
- the cap 3 is formed to have an outer diameter of the outer circumferential surface 3 b that is the same as the outer diameter of the bearing support portion 13 of the input shaft 2 .
- the third bearing 26 attached to the outer circumferential surface 3 b of the cap 3 as used is the same as the first bearing 10 attached to the bearing support portion 13 of the input shaft 2 .
- the shaking body 5 is formed in a disk shape so as to be shaken by the eccentric disk cam 4 , has a central bearing hole 30 fitted to the outer circumferential surface of the second bearing 16 , and is supported by the second bearing 16 so as to be able to turn relative to the eccentric disk cam 4 .
- a center 5 a is formed so as to be concentric with the center 4 a of the eccentric disk cam 4
- an outer circumferential surface 5 b is a cylindrical surface concentric with the center 4 a of the eccentric disk cam 4 .
- the plurality of balls 6 are rotatably supported at the outer circumferential surface 5 b .
- first through holes 31 a are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearing hole 30 .
- the first through hole 31 a of the shaking body 5 is engaged with a coupling protrusion 33 a formed on a first side face portion 32 of the first output-side rotating body 8 A with a gap therebetween, and is formed to have a size such that the first through hole 31 a does not contact the coupling protrusion 33 a even when the shaking body 5 is shaken by the eccentric disk cam 4 .
- four second through holes 31 b are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearing hole 30 .
- the second through hole 31 b of the shaking body 5 is engaged with a coupling protrusion 33 b formed on a second side face portion 41 of the second output-side rotating body 8 B with a gap therebetween, and is formed to have a size such that the second through hole 31 b does not contact the coupling protrusion 33 b even when the shaking body 5 is shaken by the eccentric disk cam 4 .
- the first through holes 31 a and the second through holes 31 b are alternately arranged at equal intervals.
- the fixing member 7 has a substantially square shape on the front side, and a shaking body housing hole 34 is formed in its central portion.
- the fixing member 7 has a fixing frame portion 35 formed along the outer edge, and a radial groove forming disk portion 36 formed on the inner side of the radial direction of the fixing frame portion 35 .
- bolt holes 37 are formed at four corners of the fixing frame portion 35 . Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixing member 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts.
- the fixing member 7 is fixed to the fixation target member such that a center 34 a of the shaking body housing hole 34 is concentric with the rotation center 2 a of the input shaft 2 .
- the shaking body 5 is housed in the shaking body housing hole 34 of the fixing member 7 so as to be able to be shaken.
- a plurality of radial grooves 38 extending along the radial direction from an inner circumferential surface 34 b of the shaking body housing hole 34 are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of a corrugated groove 60 is set to “N”).
- the radial groove 38 is an open end whose radial inner end allows the ball 6 to enter and exit, has a groove width slightly larger than the diameter of the ball 6 , and has a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (the eccentric amount e of the eccentric disk cam 4 ), so that the ball 6 supported at the outer circumferential surface 5 b of the shaking body 5 is slidably moved along the radial direction.
- a plate thickness of the radial groove forming disk portion 36 is formed smaller than the diameter of the ball 6 , so that the ball 6 is uniformly protruded on both sides of the radial groove forming disk portion 36 and the ball 6 in the radial groove 38 is rollably engaged with the corrugated groove 60 formed in the output-side rotating body 8 when the center of the ball 6 engaged with the radial groove 38 is aligned with the center position in the thickness direction of the radial groove forming disk portion 36 .
- Such radial grooves 30 of the fixing member 7 can roll the balls 6 in the radial direction depending on a shake amount of the shaking body 5 as the eccentric disk cam 4 rotates by one turn, and the shaking body 5 is shaken by one stroke.
- the plate thickness of the radial groove forming disk portion 36 of the fixing member 7 is the same as the plate thickness of a ball support portion 5 e placed on the radial outward end side of the shaking body 5 .
- the first output-side rotating body 8 A has the first side face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shaking body 5 , and one side face 36 a of both side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 . Further, in the first output-side rotating body 8 A, the bearing hole 14 for housing the first bearing 10 attached to the input shaft 2 is formed, so that the side face of the outer race of the first bearing 10 abuts on the inner protrusion 15 formed at the end of the bearing hole 14 .
- a plurality of coupling protrusions 33 a for coupling and fixing the second output-side rotating body 8 B are formed at equal intervals (in four places) in the circumferential direction.
- the coupling protrusion 33 a is inserted into the through hole 31 a of the shaking body 5 so as to be fitted in a coupling protrusion housing recess 42 b formed on a second side face portion 41 of the second output-side rotating body 8 B.
- a plurality of coupling protrusion housing recesses 42 a for coupling and fixing the second output-side rotating body 8 B are formed at equal intervals (in four places) in the circumferential direction.
- a coupling protrusion 33 b is formed extending through the through hole 31 b of the shaking body 5 on the second side face portion 41 of the second output-side rotating body 8 B so as to be fitted in the coupling protrusion housing recess 42 a .
- the corrugated groove 60 is formed on the outer side of the radial direction of the coupling protrusion 33 a and the coupling protrusion housing recess 42 a .
- screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than the coupling protrusion 33 a .
- a positioning groove 53 for positioning and fixing the second output-side rotating body 8 B with high accuracy is formed at one position on the radial outer end.
- the structures of the coupling protrusion 33 a and the coupling protrusion housing recess 42 a , and the structure for fixing the second output-side rotating body 8 B to the first output-side rotating body 8 A with bolts are the same as the structures of the ball type speed reducer 1 shown in FIGS. 1 and 11 .
- the second output-side rotating body 8 B has the second side face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shaking body 5 , and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 .
- a plurality of coupling protrusion housing recesses 42 b in which the coupling protrusions 33 are fitted are formed as many as the coupling protrusions 33 a at positions facing the respective coupling protrusions 33 a of the first output-side rotating body 8 A.
- a plurality of coupling protrusions 33 b fitted to the coupling protrusion housing recesses 42 a are formed as many as the coupling protrusion housing recesses 42 a at positions facing the respective coupling protrusion housing recesses 42 a of the first output-side rotating body 8 A.
- the bearing hole 27 for housing the third bearing 26 attached to the cap 3 is formed, so that the side face of the outer race of the third bearing 26 abuts on the inner protrusion 28 formed at the end of the bearing hole 27 .
- the corrugated groove 60 is formed on the outer side of the radial direction of the coupling protrusion 33 b and the coupling protrusion housing recess 42 b . Further, on the back face side of the second output-side rotating body 8 B (face side placed opposite to the second side face portion 41 ), screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than the coupling protrusion 33 b .
- a positioning groove 54 for positioning and fixing the first output-side rotating body 8 A with high accuracy is formed in the position (one position of the radial outer end) corresponding to the positioning groove 53 of the first output-side rotating body 8 A.
- Such a second output-side rotating body 8 B has a shape as the second side face portion 41 is viewed in plan (a shape shown in FIG. 21A ) that is the same as the shape as the first output-side rotating body 8 A is viewed in plan ( FIG. 20A ). Further, the second output-side rotating body 8 B has the same longitudinal sectional shape (the sectional shape shown in FIG. 20C ) as the longitudinal sectional shape of the first output-side rotating body 8 A (the sectional shape shown in FIG.
- the corrugated groove 60 is formed to have waves in which a portion located at a radial inner end of a wave is referred to as a bottom 60 a and a portion located at a radial outer end of the wave is referred to as a top 60 b , the bottom 60 a and the top 60 b are formed equally across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B, so that the bottom 60 a and the top 60 b in the first side face portion 32 and the second side face portion 41 have the same groove depth. Further, as shown in FIG.
- the corrugated groove 60 is formed such that in regard to the first side face portion 32 of the first output-side rotating body 8 A, the groove depth gradually decreases from the bottom 60 a on a center line 61 toward the top 60 b on the right and then gradually increases, and the groove depth gradually increases from the top 60 b toward the bottom 60 a on the right and then gradually decreases. Further, as shown in FIG.
- the corrugated groove 60 is formed such that in regard to the second side face portion 41 of the second output-side rotating body 8 B facing the first side face portion 32 of the first output-side rotating body 8 A, the groove depth gradually increases from the bottom 60 a on the center line 61 toward the top 60 b on the left and then gradually decreases, and the groove depth gradually decreases from the top 60 b toward the bottom 60 a on the left and then gradually increases. That is, the corrugated groove 60 formed across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B spirally guides the ball 6 along the circumferential direction of the first output-side rotating body 8 A and the second output-side rotating body 8 B.
- the ball 6 which is engaged with the corrugated groove 60 formed across the first output-side rotating body 8 A and the second output-side rotating body 8 B and also the radial groove 38 of the fixing member 7 , is also moved in the direction along the rotation center 2 a of the input shaft 2 by following the three-dimensionally formed corrugated groove 60 .
- the corrugated groove 60 is formed across the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B as described above, the corrugated groove 60 is shaped with high precision without any deviation between the corrugated groove 60 on the first output-side rotating body 8 A side and the corrugated groove 60 on the second output-side rotating body 8 B side.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B are fixed, the first output-side rotating body 8 A and the second output-side rotating body 8 B are in a state of being positioned with high accuracy by aligning a positioning groove 53 of the first output-side rotating body 8 A with a positioning groove 54 of the second output-side rotating body 8 B (see FIGS. 14, 20A-20C, and 21A-21C ).
- the corrugated groove 60 has only to guide the ball 6 in a right-handed spiral or a left-handed spiral along the circumferential direction of the first output-side rotating body 8 A and the second output-side rotating body 8 B.
- FIGS. 22A-22C illustrating a rolling trajectory 62 of the ball 6 when the ball 6 is rolled in the corrugated groove 60 .
- FIG. 22A is a plan view illustrating the rolling trajectory 62 of the ball 6 (rolling trajectory 62 projected on a virtual plane perpendicular to the rotation center 2 a of the input shaft 2 ).
- FIG. 22B is a diagram illustrating adjacent waves W 1 and W 2 in the rolling trajectory 62 projected on a virtual cross section taken along the line A 15 -A 15 of FIG. 22A .
- FIG. 22C is an enlarged view illustrating the rolling trajectory of the ball of FIG. 22B .
- the rolling trajectory 62 of the ball 6 shown in FIGS. 22A-22C indicates a groove shape of the corrugated groove 60 .
- R represents the radial direction
- Z represents the direction along the rotation center 2 a of the input shaft 2 .
- the rolling trajectory 62 of the ball 6 moving along the corrugated groove 60 traces an elliptical shape whose major axis is the R direction.
- the center of the ball 6 is located in the middle between the first side face portion 32 and the second side face portion 41 at each of the bottom 60 a and the top 60 b of the corrugated groove 60 (a bottom 62 a and a top 62 b of the rolling trajectory 62 ).
- the amount of movement in the +Z direction is gradually increased from the bottom 62 a of the first wave W 1 toward the top 62 b of the first wave W 1 and then gradually decreased, and the amount of movement in the ⁇ Z direction is gradually increased from the top 62 b of the first wave W 1 toward the bottom 62 a of the adjacent second wave W 2 and then gradually decreased.
- the amount of movement in the +Z direction is the same as the amount of movement in the ⁇ Z direction.
- Such a rolling trajectory 62 of the ball 6 is shaped by the corrugated groove 60 formed across the first output-side rotating body 8 A and the second output-side rotating body 8 B.
- FIGS. 23A-24B are diagrams illustrating features of the corrugated groove 60 of the ball type speed reducer 1 according to this embodiment.
- FIG. 23A illustrates an arrangement in which balls 6 are located at the top 62 b in the rolling trajectory 62 of the ball 6 (a partial plan view illustrating the rolling trajectory 62 )
- FIG. 23B is a cylindrical cross-sectional view taken at the position corresponding to the line A 16 -A 16 of FIG. 23A to illustrate the ball type speed reducer 1
- FIG. 24A illustrates an arrangement in which balls 6 are located at a middle position between the top 62 b and the bottom 62 a in the rolling trajectory 62 of the ball 6 (a partial plan view illustrating the rolling trajectory 62 )
- FIG. 24B is a cylindrical cross-sectional view taken at the position corresponding to the line A 17 -A 17 of FIG. 24A to illustrate the ball type speed reducer 1 .
- the top 62 b of the rolling trajectory 62 of the ball 6 is positioned at one end of the major axis of the elliptical rolling trajectory 62 of FIG. 22C .
- the corrugated groove 60 has the same groove depth at each of the first output-side rotating body 8 A and the second output-side rotating body 8 B (the groove depth from the first side face portion 32 and the groove depth from the second side face portion 41 are the same).
- a ridge portion 63 having the same ridge height h 1 is formed between the adjacent balls 6 , 6 .
- the cylindrical cross-sectional view at the bottom 62 a of the rolling trajectory 62 of the ball 6 is the same as FIG. 23B .
- the middle position between the top 62 b and the bottom 62 a of the rolling trajectory 62 of the ball 6 corresponds to the position of the minor axis of the elliptical rolling trajectory 62 of FIG. 22C .
- the corrugated groove 60 has the same groove depth at each of the first output-side rotating body 8 A and the second output-side rotating body 8 B (the groove depth from the first side face portion 32 and the groove depth from the second side face portion 41 are the same).
- a ridge portion 63 having the same ridge height h 2 is formed between the adjacent balls 6 , 6 .
- the corrugated groove 60 engaged with the ball 6 is formed in a spiral shape in the first output-side rotating body 8 A and the second output-side rotating body 8 B (see FIGS. 22A-22C ), the ridge portion 63 having the sufficient ridge height h 1 or h 2 that can prevent ratcheting is formed between the adjacent balls 6 , 6 at any of the position of the bottom 60 a of the corrugated groove 60 , the middle position between the bottom 60 a and the top 60 b of the corrugated groove 60 , and the position of the top 60 b of the corrugated groove 60 .
- the corrugated grooves 60 are formed only in two places: the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B, it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (see FIGS. 35A and 35B ) in which the corrugated grooves 111 , 111 , 112 , and 112 are formed in four places. Further, in the ball type speed reducer 1 according to this embodiment, the shaking body 5 can be shaken independently from the fixing member 7 and the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B).
- the ball 6 is positioned in a portion where the radial groove 38 and the corrugated groove 60 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which the balls 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentric rotating plate 104 and the groove wall of the second corrugated groove 112 of the fixing member 107 (see FIGS. 35A and 35B ), it is possible to facilitate machining of the radial groove 38 and the corrugated groove 60 and an assembly work for the shaking body 5 , the fixing member 7 , the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B), and the like.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B have the same shape, so that their parts (the first output-side rotating body 8 A, the second output-side rotating body 8 B, the first bearing 10 , and the third bearing 26 ) can be made common, thereby making it possible to reduce the parts cost.
- the technical concept of the ball type speed reducer 1 according to this embodiment can be applied to the ball type speed reducer 1 according to the first embodiment and the ball type speed reducer 1 according to the second embodiment.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B have the same shape, so that their parts (the first output-side rotating body 8 A, the second output-side rotating body 8 B, the first bearing 10 , and the third bearing 26 ) are made common, thereby making it possible to reduce the parts cost.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B can have the same shape.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B have the same shape, so that their parts (the first output-side rotating body 8 A, the second output-side rotating body 8 B, the first bearing 10 , and the third bearing 26 ) are made common, thereby making it possible to reduce the parts cost.
- FIG. 25A is a diagram illustrating a first modification of the rolling trajectory 62 of the ball 6 , and corresponding to FIG. 22C .
- the rolling trajectory 62 of the ball 6 shown in FIG. 25A is a pair of arcs 64 , 64 facing each other to form a substantially elliptical shape, and has a line symmetry shape in which a center line 65 extending along the Z-axis direction is taken as a symmetry axis and also a line symmetry shape in which a center line 66 extending along the R direction is taken as a symmetry axis.
- the corrugated groove 60 of the ball type speed reducer 1 may be formed to have the rolling trajectory 62 of the ball 6 shown in FIG. 25A .
- FIG. 25B is a diagram illustrating a second modification of the rolling trajectory 62 of the ball 6 , and corresponding to FIG. 22C .
- the rolling trajectory 62 of the ball 6 shown in FIG. 25B is a pair of arc-like shapes facing each other to form a substantially elliptical shape in which both end sections of the arc 64 in FIG. 25A are replaced with straight lines 67 , 67 , and has a line symmetry shape in which a center line 65 extending along the Z-axis direction is taken as a symmetry axis and also a line symmetry shape in which a center line 66 extending along the R direction is taken as a symmetry axis.
- the corrugated groove 60 of the ball type speed reducer 1 may be formed to have the rolling trajectory 62 of the ball 6 shown in FIG. 25B .
- FIGS. 26A-27 are diagrams illustrating a ball type speed reducer 1 according to a fourth embodiment of the invention. Note that FIG. 26A is a front view illustrating the ball type speed reducer 1 , and FIG. 26B is a side view illustrating the ball type speed reducer 1 . FIG. 27 is a cross-sectional view taken along the line A 18 -A 18 of FIG. 26A to illustrate the ball type speed reducer 1 .
- the ball type speed reducer 1 includes an input shaft (input-side rotating body) 2 , a cap (input-side rotating body) 3 , an eccentric disk cam 4 , a shaking body 5 (a first shaking body 5 A and a second shaking body 5 B), a plurality of balls (steel balls) 6 , a fixing member 7 , an output-side rotating body 8 (a first output-side rotating body 8 A and a second output-side rotating body 8 B), and the like.
- FIG. 27 is a front view illustrating the ball type speed reducer 1 in which the cap 3 , the second output-side rotating body 8 B, and the like are removed.
- the input shaft 2 turnably supports the first output-side rotating body 8 A by interposing a first bearing 10 , so that the input shaft 2 is rotationally driven by a motor or the like (not shown).
- the input shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of a shaft body portion 11 is adjacent to the shaft body portion 11 .
- a bearing support portion 13 is formed adjacent to the flange-like portion 12 .
- the first bearing 10 is attached to the bearing support portion 13 to hold the first bearing 10 between an inner protrusion 15 of a bearing hole 14 of the first output-side rotating body 8 A and the flange-like portion 12 .
- the input shaft 2 has the eccentric disk cam 4 formed closer to a shaft tip side than the bearing support portion 13 and in the vicinity of the bearing support portion 13 .
- This eccentric disk cam 4 is a decentered shaft portion having a center 4 a decentered from a rotation center 2 a of the input shaft 2 (a rotation center 11 a of the shaft body portion 11 ) by an eccentric amount “e,” and is eccentrically rotated integrally with the input shaft 2 by virtue of rotation of the rotation center 2 a of the input shaft 2 .
- the shaking body 5 is relatively turnably installed in the outer circumference side of the eccentric disk cam 4 by interposing a second bearing 16 .
- the input shaft 2 has a tip shaft portion 17 formed to install the cap 3 .
- the tip shaft portion 17 has a rotation center concentric with the rotation center 2 a of the shaft body portion 2 and fitted in a shaft hole 18 of the cap 3 and has a leading end face 17 a abutting on a stopper protrusion 20 protruding into the shaft hole 18 of the cap 3 . Further, in the tip shaft portion 17 of the input shaft 2 , a screw hole (female screw) 22 to be screwed with a screw shaft portion 21 a of a bolt 21 for fixing the cap 3 is formed.
- the cap 3 is fixed to the tip shaft portion 17 of the input shaft 2 with the bolt 21 , constitutes an input-side rotating body together with the input shaft 2 , and has a rotation center 3 a coinciding with the rotation center 2 a .
- the cap 3 has the shaft hole 18 opened at one end side (right end side in FIG. 30D ) along a rotation center 3 a , a bolt head housing hole 23 opened at the other end side along the rotation center 3 a (left end side in FIG. 30D ), and a bolt shaft insertion hole 24 through which the bolt head housing hole 23 and the shaft hole 18 are communicated with each other.
- the cap 3 has a ring-shaped bearing stopper 25 on the left end side of a cylindrical outer circumferential surface 3 b .
- a side face of a third bearing 26 attached to the outer circumferential surface 3 b abuts on the bearing stopper 25 , so that the third bearing 26 is held between an inner protrusion 28 in the bearing hole 27 of the second output-side rotating body 8 B and the bearing stopper 25 .
- the rotation center of the shaft hole 18 and the rotation center of the outer circumferential surface 3 b are concentric with the rotation center 3 a of the cap 3 .
- the cap 3 is formed to have an outer diameter of the outer circumferential surface 3 b that is the same as the outer diameter of the bearing support portion 13 of the input shaft 2 .
- the third bearing 26 attached to the outer circumferential surface 3 b of the cap 3 as used is the same as the first bearing 10 attached to the bearing support portion 13 of the input shaft 2 .
- the cap 3 holds the second bearing 16 in a state where the second bearing 16 is positioned between a bearing positioning step 3 c and a bearing positioning step 2 b of the input shaft 2 .
- the shaking body 5 is obtained by combining the first shaking body 5 A and the second shaking body 5 B which are the same shape, back to back.
- the shaking body 5 is bifurcated into a first edge portion 5 f (an outer circumferential edge portion of the first shaking body 5 A) and a second edge portion 5 g (an outer circumferential edge portion of the second shaking body 5 B) on the outer circumferential end side.
- the first edge portion 5 f is slidably engaged with one side face side of the fixing member 7
- the second edge portion 5 g is slidably engaged with the other side face side of the fixing member 7 .
- the first shaking body 5 A is formed in a disk shape so as to be shaken by the eccentric disk cam 4 , has a central bearing hole 30 fitted to the outer circumferential surface of the second bearing 16 , and is supported by the second bearing 16 so as to be able to turn relative to the eccentric disk cam 4 .
- a center 5 a is formed so as to be concentric with the center 4 a of the eccentric disk cam 4
- an outer circumferential surface 5 b is a cylindrical surface concentric with the center 4 a of the eccentric disk cam 4 .
- the plurality of balls 6 are rotatably supported at the outer circumferential surface 5 b .
- first shaking body 5 A ten through holes 31 are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearing hole 30 .
- the through hole 31 of the first shaking body 5 A is engaged with a coupling protrusion 33 a formed on a first side face portion 32 of the first output-side rotating body 8 A and a coupling protrusion 33 b formed on a second side face portion 41 of the second output-side rotating body 8 B with a gap therebetween, and is formed to have a size such that the second through hole 31 b does not contact the coupling protrusions 33 a and 33 b even when the first shaking body 5 A is shaken by the eccentric disk cam 4 .
- the outer circumferential surface 5 b of the first edge portion 5 f of the first shaking body 5 A has an arc-like cross-sectional shape that can come in line contact with the outer circumferential surface of the ball 5 (see FIG. 31F ). Note that, since the second shaking body 5 B has the same shape as the first shaking body 5 A, the same parts as those of the first shaking body 5 A will not be repeatedly described.
- the fixing member 7 has a substantially square shape on the front side, and a shaking body housing hole 34 is formed in its central portion.
- the fixing member 7 has a fixing frame portion 35 formed along the outer edge, and a radial groove forming disk portion 36 formed on the inner side of the radial direction of the fixing frame portion 35 .
- bolt holes 37 are formed at four corners of the fixing frame portion 35 . Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixing member 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts.
- the fixing member 7 is fixed to the fixation target member such that a center 34 a of the shaking body housing hole 34 is concentric with the rotation center 2 a of the input shaft 2 .
- the shaking body 5 (the first shaking body 5 A and the second shaking body 5 B) is housed in the shaking body housing hole 34 of the fixing member 7 so as to be able to be shaken.
- the first edge portion 5 f of the shaking body 5 (the outer circumferential edge portion of the first shaking body 5 A) is disposed to face one side face 36 a of the fixing member 7 .
- the second edge portion 5 g of the shaking body 5 (the outer circumferential edge portion of the second shaking body 5 B) is disposed to face the other side face 36 b of the fixing member 7 .
- a plurality of elongated hole-shaped first radial grooves 68 extending along the radial direction are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of a corrugated groove 70 is set to “N”).
- a plurality of elongated hole-shaped second radial grooves 71 extending along the radial direction are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of the corrugated groove 70 is set to “N”).
- the second radial grooves 71 are formed at positions when the first radial grooves 68 are deviated by a half pitch in the circumferential direction (an angle of ⁇ /2 where ⁇ is the angle between the adjacent first radial grooves 68 , 68 ) so that the first radial grooves 68 are turned upside down, and are also formed at the same positions in the radial direction as the first radial grooves 68 .
- the first radial groove 68 and the second radial groove 71 are formed such that their groove depth is smaller than the radius of the ball 6 and their groove shape has an arc shape with the same radius as the radius of the ball 6 , and are also formed in line contact with the balls 6 .
- first radial groove 68 and the second radial groove 71 are formed to have a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (an eccentric amount “e” of the eccentric disk cam 4 ), so that the ball 6 supported at the outer circumferential surface 5 b of the shaking body 5 is slidably moved along the radial direction.
- the ball 6 housed in the first radial groove 68 is rollably engaged with the corrugated groove 70 of the first output-side rotating body 8 A.
- the ball 6 housed in the second radial groove 71 is rollably engaged with the corrugated groove 70 of the second output-side rotating body 8 B.
- Such first radial grooves 68 and second radial grooves 71 of the fixing member 7 can roll the balls 6 in the radial direction depending on a shake amount of the shaking body 5 as the eccentric disk cam 4 rotates by one turn, and the shaking body 5 is shaken by one stroke.
- the first radial groove 68 formed on one side face 36 a of the radial groove forming disk portion 36 and the second radial groove 71 formed on the other side face 36 b are deviated from each other in the circumferential direction by a half pitch (angle of ⁇ /2). Therefore, compared to the case where the first radial groove 68 and the second radial groove 71 are formed at the same position in the circumferential direction (the case where they are not deviated from each other in the circumferential direction), the thickness of the radial groove forming disk portion 36 can be sufficiently secured, and the strength of the radial groove forming disk portion 36 can be increased.
- the first radial groove 68 formed on one side face 36 a and the second radial groove 71 formed on the other side face 36 b are deviated from each other in the circumferential direction by a half pitch. Therefore, compared to the case where the first radial groove 68 and the second radial groove 71 are formed at the same position in the circumferential direction (the case where they are not deviated from each other in the circumferential direction), the thickness of the radial groove forming disk portion 36 can be reduced while the strength of the radial groove forming disk portion 36 is maintained constant, thereby making it possible to achieve a light weight.
- the first output-side rotating body 8 A has the first side face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shaking body 5 , and one side face 36 a of both side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 . Further, in the first output-side rotating body 8 A, the bearing hole 14 for housing the first bearing 10 attached to the input shaft 2 is formed, so that the side face of the outer race of the first bearing 10 abuts on the inner protrusion 15 formed at the end of the bearing hole 14 .
- a plurality of coupling protrusions 33 a for coupling and fixing the second output-side rotating body 8 B are formed at equal intervals (in five places) in the circumferential direction.
- the coupling protrusion 33 a is inserted into the through hole 31 of the shaking body 5 so as to be fitted in a coupling protrusion housing recess 42 b formed on a second side face portion 41 of the second output-side rotating body 8 B.
- a plurality of coupling protrusion housing recesses 42 a for coupling and fixing the second output-side rotating body 8 B are formed at equal intervals (in five places) in the circumferential direction.
- a coupling protrusion 33 b is formed extending through the through hole 31 of the shaking body 5 on the second side face portion 41 of the second output-side rotating body 8 B so as to be fitted in the coupling protrusion housing recess 42 a .
- the coupling protrusion 33 a and the coupling protrusion housing recess 42 a are alternately arranged at equal intervals around a center C 1 of the first output-side rotating body 8 A.
- the corrugated groove 70 is formed on the outer side of the radial direction of the coupling protrusion 33 a and the coupling protrusion housing recess 42 a .
- 50 waves are continuously formed in the corrugated groove 70 .
- the corrugated groove 70 is formed such that the top of the wave is placed on a center line 72 which passes through the center C 1 of the first output-side rotating body 8 A and is parallel to the x direction.
- one of the coupling protrusions 33 a and one of the coupling protrusion housing recesses 42 a located at a two-fold symmetrical position with the one of the coupling protrusions 33 a are arranged on a center line 74 which is deviated counterclockwise by a 1 ⁇ 4 pitch (an angle of ⁇ /4 where ⁇ is the angle between the adjacent first radial grooves 68 , 68 ) of the first radial groove 68 with respect to a center line 73 (center line passing through the center C 1 of the first output-side rotating body 8 A and parallel to the y direction) perpendicular to the center line 72 .
- screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than the coupling protrusion 33 a .
- the screw holes 52 are formed at a pair of positions on the center line 74 , and are formed at a pair of positions on a center line 75 perpendicular to the center line 74 .
- the radial groove forming disk portion 36 of the fixing member 7 , the first edge portion 5 f of the shaking body 5 , and the second edge portion 5 g of the shaking body 5 are housed between the second side face portion 41 of the second output-side rotating body 8 B and a portion radially inward of the corrugated groove 70 (more precisely, a region which enables the shaking body 5 to shake).
- the first side face portion 32 of the first output-side rotating body 8 A only the radial groove forming disk portion 36 of the fixing member 7 is housed between the second side face portion 41 of the second output-side rotating body 8 B and a portion radially outward of the corrugated groove 70 (more precisely, a region where the outer circumferential end of the shaking body 5 does not reach). Therefore, in the first side face portion 32 of the first output-side rotating body 8 A, since the corrugated groove 70 is formed such that the groove depth of the first radial groove 68 formed on one side face 36 a of the fixing member 7 is smaller than the radius of the ball 6 , the groove depth on the top side can be made larger than the radius of the ball 6 . As a result, the first output-side rotating body 8 A can effectively prevent the ratcheting in the vicinity of the top of the corrugated groove 70 where the largest rotational torque acts when the rotation of the ball type speed reducer 1 is transmitted.
- FIGS. 34A-34D are diagrams illustrating the second output-side rotating body 8 B.
- the second output-side rotating body 8 B shown in FIG. 34A is obtained in such a manner that the first output-side rotating body 8 A is turned upside down around the center line (reversal reference center line) 72 of FIG. 33A , then the first output-side rotating body 8 A is rotated 180 degrees around the center line 73 , and subsequently the first output-side rotating body 8 A is rotated clockwise around the center C 1 of the first output-side rotating body 8 A by a half pitch of the second radial groove 71 (an angle of ⁇ /2 where ⁇ is the angle between the adjacent radial grooves 71 , 71 ).
- the second output-side rotating body 8 B as used has the same shape as the first output-side rotating body.
- the second output-side rotating body 8 B has the second side face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shaking body 5 , and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove forming disk portion 36 of the fixing member 7 .
- a plurality of coupling protrusion housing recesses 42 b fitted to the coupling protrusions 33 are formed as many as the coupling protrusions 33 a at positions corresponding to the respective coupling protrusions 33 a of the first output-side rotating body 8 a .
- a plurality of coupling protrusions 33 b fitted to the coupling protrusion housing recesses 42 a are formed as many as the coupling protrusion housing recesses 42 a at positions corresponding to the respective coupling protrusion housing recesses 42 a of the first output-side rotating body 8 A.
- the bearing hole 27 for housing the third bearing 26 attached to the cap 3 is formed, so that the side face of the outer race of the third bearing 26 abuts on the inner protrusion 28 formed at the end of the bearing hole 27 .
- screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than the coupling protrusion 33 b.
- the corrugated groove 70 is formed on the outer side of the radial direction of the coupling protrusion 33 b and the coupling protrusion housing recess 42 b . As shown in FIG. 34A, 50 waves are continuously formed in the corrugated groove 70 .
- the corrugated groove 70 is formed such that the top of the wave is placed on a center line 76 rotated clockwise by ⁇ /2 from the center line 72 which passes through the center C 1 of the second output-side rotating body 8 B and is parallel to the x direction.
- one of the coupling protrusions 33 b and one of the coupling protrusion housing recesses 42 b located at a two-fold symmetrical position with the one of the coupling protrusions 33 b are arranged on the center line 74 perpendicular to the center line 75 .
- first output-side rotating body 8 A and the second output-side rotating body 8 B are fixed in such a manner that a shaft portion 78 a of a bolt 78 inserted into a bolt hole 77 formed in the coupling protrusion housing recess 42 b of the second output-side rotating body 8 B is screwed into a female screw portion 80 of the coupling protrusion 33 a of the first output-side rotating body 8 A; a shaft portion 78 a of a bolt 78 inserted into a bolt hole 77 formed in the coupling protrusion housing recess 42 a of the first output-side rotating body 8 A is screwed into a female screw portion 80 of the coupling protrusion 33 b of the second output-side rotating body 8 B.
- the radial groove forming disk portion 36 of the fixing member 7 , the first edge portion 5 f of the shaking body 5 , and the second edge portion 5 g of the shaking body 5 are housed between the first side face portion 32 of the first output-side rotating body 8 A and a portion radially inward of the corrugated groove 70 (more precisely, a region which enables the shaking body 5 to shake).
- the second side face portion 41 of the second output-side rotating body 8 B only the radial groove forming disk portion 36 of the fixing member 7 is housed between the first side face portion 32 of the first output-side rotating body 8 A and a portion radially outward of the corrugated groove 70 (more precisely, a region where the outer circumferential end of the shaking body 5 does not reach). Therefore, in the second side face portion 41 of the second output-side rotating body 8 B, since the corrugated groove 70 is formed such that the groove depth of the second radial groove 71 formed on the other side face 36 b of the fixing member 7 is smaller than the radius of the ball 6 , the groove depth on the top side can be made larger than the radius of the ball 6 . As a result, the second output-side rotating body 8 B can effectively prevent the ratcheting in the vicinity of the top of the corrugated groove 70 where the largest rotational torque acts when the rotation of the ball type speed reducer 1 is transmitted.
- the corrugated groove 70 of the first output-side rotating body 8 A and the corrugated groove 70 of the second output-side rotating body 8 B are placed to be deviated from each other by a half pitch ( ⁇ /2) of the first radial groove 68 (or the second radial groove 71 ) in the circumferential direction.
- the positional relationship between the first radial groove 68 of the fixing member 7 and the corrugated groove 70 of the first output-side rotating body 8 A matches the positional relationship between the second radial groove 71 of the fixing member 7 and the corrugated groove 70 of the second output-side rotating body 8 B, thereby making it possible to achieve smooth rotation transmission.
- the corrugated grooves 70 are formed only in two places: the first side face portion 32 of the first output-side rotating body 8 A and the second side face portion 41 of the second output-side rotating body 8 B, it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (see FIGS. 35A and 35B ) in which the corrugated grooves 111 , 111 , 112 , and 112 are formed in four places. Further, in the ball type speed reducer 1 according to this embodiment, the shaking body 5 can be shaken independently from the fixing member 7 and the output-side rotating body 8 (the first output-side rotating body 8 A and the second output-side rotating body 8 B).
- the balls 6 are positioned in a portion where the first radial groove 68 and the corrugated groove 70 intersect and in a portion where the second radial groove 71 and the corrugated groove 70 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which the balls 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentric rotating plate 104 and the groove wall of the second corrugated groove 112 of the fixing member 107 (see FIGS.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B have the same shape, so that their parts (the first output-side rotating body 8 A, the second output-side rotating body 8 B, the first bearing 10 , and the third bearing 26 ) can be made common, thereby making it possible to reduce the parts cost.
- the first radial groove 68 and the second radial groove 71 of the fixing member 7 are formed to be deviated from each other by a half pitch ( ⁇ /2) along the circumferential direction.
- the first radial groove 68 and the second radial groove 71 of the fixing member 7 may be formed at the same position in the circumferential direction.
- one of the coupling protrusions 33 a of the first output-side rotating body 8 A and one of the coupling protrusion housing recesses 42 a located at a two-fold symmetrical position with the one of the coupling protrusions 33 a are arranged on the center line 73 (the center line passing through the center C 1 of the first output-side rotating body 8 A and parallel to the y direction).
- the shaking body 5 is obtained by combining the first shaking body 5 A and the second shaking body 5 B which are the same shape, back to back.
- the shaking body 5 may be integrally formed as a whole.
- a ball bearing, a roller bearing, a bush or the like is used as the first to third bearings 10 , 16 , and 26 .
- the entire assembly of the speed reducer (including the input shaft 2 , the cap 3 , the shaking body 5 , the fixing member 7 , the first output-side rotating body 8 A, the second output-side rotating body 8 B, and the like) may be formed of metal, a part of the assembly may be formed of a synthetic resin material, or the entire assembly except for the first to fourth bearings 10 , 16 , and 26 and the balls 6 may be formed of a synthetic resin material.
- the ball type speed reducer 1 in which the entire assembly except for the first to third bearings 10 , 16 , and 26 and the balls 6 is formed of a synthetic resin material, it is possible to reduce the weight and lower the product cost. Further, in the ball type speed reducer 1 in which the entire assembly except for the first to third bearings 10 , 16 , and 26 and the balls 6 is formed of a synthetic resin material, it is possible to reduce a contact sound of the ball 6 (noise reduction) and suppress vibration.
- the first output-side rotating body 8 A and the second output-side rotating body 8 B can be made common, and accordingly one die is enough to injection molding, thereby making it possible to reduce the manufacturing cost.
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Abstract
A ball type speed reducer includes: an eccentric disk cam that turns integrally with an input-side rotating body; a shaking body shaken by the eccentric disk cam; a plurality of balls supported by the shaking body; a fixing member; a first output-side rotating body facing one side face of the fixing member; and a second output-side rotating body facing the other side face of the fixing member. A plurality of radial grooves guide the ball along the radial direction in the fixing member. A corrugated groove spirally guiding the ball along the circumferential direction is formed across the first output-side rotating body and the second output-side rotating body. The groove depth at the top of a wave of the corrugated groove is greater than that at the bottom of the wave, in an alternating manner on the first output-side rotating body side and the second output-side rotating body side.
Description
- The present invention relates to a ball type speed reducer used for decelerating and transmitting rotation.
- In the prior art, a ball type speed reducer is used in a power transmission unit of various types of machines (such as an industrial robot or a steering angle variable type steering system) because it is small-sized and can obtain a larger reduction ratio, compared to a mechanical reduction gear.
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FIGS. 35A and 35B are diagrams illustrating the ball type speed reducer 100 of the prior art. Note thatFIG. 35A is a longitudinal cross-sectional view illustrating the ball type speed reducer 100 of the prior art, andFIG. 35B is a cross-sectional view taken along the line A18-A18 ofFIG. 35A to illustrate the ball type speed reducer 100. - As illustrated in
FIGS. 35A and 35B , the ball type speed reducer 100 has aneccentric rotating plate 104 installed in an outer circumference side of aneccentric cam 102 provided in aninput shaft 101 by interposing abearing 103, so that the eccentricrotating plate 104 is eccentrically driven by theeccentric cam 102. Further, in this ball type speed reducer 100, an output-side rotatingbody 105 coupled to an output shaft (not shown) is disposed in both inner sides of a radial direction of theeccentric rotating plate 104, and theinput shaft 101 is relatively turnably supported by an inner circumference side of the output-side rotatingbody 105 by interposing abearing 106. Further, in this ball type speed reducer 100, afixing member 107 fixed to a part of an industrial robot or the like is disposed in both outer sides of the radial direction of the eccentric rotatingplate 104 by interposingballs 108, and the output-side rotatingbody 105 is turnably supported by the inner circumference side of thefixing member 107 by interposing abearing 110. In addition, theballs 108 interposed between the eccentricrotating plate 104 and thefixing member 107 are rollably engaged with a first corrugated groove (first cycloid groove formed in an epicycloid curve) 111 formed on a side face of the eccentricrotating plate 104 and a second corrugated groove (second cycloid groove formed in a hypocycloid curve) 112 formed on the inner side face (side face facing the eccentric rotating plate 104) of thefixing member 107 to connect theeccentric rotating plate 104 and thefixing member 107. Note that the number of waves of the secondcorrugated groove 112 is larger than the number of waves of the first corrugated groove 111 by two waves. - Further, the output-side rotating
body 105 is connected to the eccentric rotatingplate 104 by interposing aneccentricity absorption mechanism 113. Theeccentricity absorption mechanism 113 allows the eccentricrotating plate 104 to make an eccentric motion against the output-side rotating body 105 (to absorb eccentricity of the eccentric rotating plate 104) and transmits rotation of the eccentricrotating plate 104 to the output-side rotatingbody 105. Theeccentricity absorption mechanism 113 has a plurality ofballs 114 interposed between the eccentricrotating plate 104 and the output-side rotatingbody 105, a drivingannular groove 115 of the eccentricrotating plate 104 that rollably houses theballs 114, and a followerannular groove 116 of the output-side rotatingbody 105. The drivingannular groove 115 and the followerannular groove 116 have shapes and sizes determined by considering the eccentric amount of theeccentric cam 102, and the eccentricrotating plate 104 allows a movement of theball 114 for making eccentric rotation with respect to a rotation center of theinput shaft 101 to turn the output-side rotatingbody 105 integrally with theeccentric rotating plate 104 by interposing the balls 114 (see Patent Document 1). - In such a ball type speed reducer 100 of the prior art, for example, when the number of waves of the first corrugated groove 111 of the eccentric
rotating plate 104 is set to “N−2,” and the number of waves of the secondcorrugated groove 112 of thefixing member 107 is set to “N,” as theinput shaft 101 is rotationally driven by a motor (not shown) or the like, the eccentricrotating plate 104 is eccentrically driven by theeccentric cam 102 of theinput shaft 101, and the output-side rotatingbody 105 rotates integrally with the eccentricrotating plate 104 by interposing theeccentricity absorption mechanism 113. However, the output-side rotatingbody 105 rotates by “−2/(N−2)” for one rotation of the input shaft 101 (rotation by “2/(N−2)” oppositely to the rotational direction of the input shaft 101). That is, the ball type speed reducer 100 of the prior art has a reduction ratio of “2/(N−2)” when the number of waves of the first corrugated groove 111 of the eccentricrotating plate 104 is set to “N−2,” and the number of waves of the secondcorrugated groove 112 of thefixing member 107 is set to “N.” - Patent Document 1: Japanese Unexamined Patent Application Publication No. 5-10400
- However, in the ball type speed reducer 100 of the prior art illustrated in
FIGS. 35A and 35B , the first corrugated groove 111 is formed in both side faces of the eccentricrotating plate 104, and the secondcorrugated groove 112 is formed on the inner side face of thefixing member 107 disposed in both sides of the eccentricrotating plate 104. Therefore, it is necessary to form thecorrugated grooves - Further, in the ball type speed reducer 100 of the prior art illustrated in
FIGS. 35A and 35B , in order to turn the eccentricrotating plate 104 and the output-side rotatingbody 105 integrally, the output-side rotatingbody 105 is connected to the eccentricrotating plate 104 by interposing theeccentricity absorption mechanism 113. Therefore, it has a complicated structure, and increases man-hours disadvantageously. - In view of the aforementioned problems, it is therefore an object of the present invention to provide a ball type speed reducer having a simple structure and reduced man-hours.
- The present invention relates to a ball type speed reducer 1 that decelerates and transmits rotation of an input-side rotating body (2, 3) to an output-side rotating
body 8. The ball type speed reducer 1 of the present invention includes: aneccentric disk cam 4 turning integrally with the input-side rotating body (2, 3); a shakingbody 5 fitted relatively turnably to an outer circumference side of theeccentric disk cam 4 and shaken by theeccentric disk cam 4; a plurality ofballs 6 disposed along an outer circumferential surface 5 b of the shakingbody 5; afixing member 7 housing the shakingbody 5 in an inner side of a radial direction such that the shakingbody 5 is shakable and fixed to a fixation target member; a first output-side rotatingbody 8A disposed to face one side face of the shakingbody 5 and thefixing member 7 and relatively turnably supported by the input-side rotating body (2, 3); and a second output-side rotatingbody 8B disposed to face the other side face of the shakingbody 5 and thefixing member 7 and integrally turnably fixed to the first output-side rotatingbody 8A, and relatively turnably supported by the input-side rotating body (2, 3) and constituting the output-side rotatingbody 8 together with the first output-side rotatingbody 8A. In addition, the outer circumferential surface 5 b of the shakingbody 5 is a cylindrical surface concentric with acenter 4 a of theeccentric disk cam 4. Further, when a direction extending radially from arotation center 2 a of the input-side rotating body (2, 3) is set as a radial direction on a virtual plane perpendicular to therotation center 2 a, thefixing member 7 has a plurality ofradial grooves 38 as many as theballs 6 formed to slidably guide theballs 6 in the radial direction, and radial inner ends of theradial grooves 38 are open ends allowing theballs 6 to enter and exit. Further, the first output-side rotatingbody 8A has a firstside face portion 32 opposed to one side face of thefixing member 7. Further, the second output-side rotatingbody 8B has a secondside face portion 41 opposed to the other side face of thefixing member 7. Further, when a direction extending along an outer edge of a virtual circle centered at therotation center 2 a on the virtual plane is set as a circumferential direction, the firstside face portion 32 and the secondside face portion 41 each have annularcorrugated grooves balls 6 along the circumferential direction. - The ball type speed reducer according to the present invention has the corrugated groove formed only in two places: at the first side face portions of the first output-side rotating body and the second side face portions of the second output-side rotating body, which face the shaking body and the fixing member. Therefore, it is possible to reduce the man-hours, compared to the prior art in which the corrugated groove is formed in each of four side faces. Further, the ball type speed reducer according to the present invention has the shaking body that can be shaken independently from the output-side rotating body (the first output-side rotating body and the second output-side rotating body) and the fixing member. Therefore, it is not necessary to provide a complicated mechanism for turning the output-side rotating body and the shaking body integrally. Accordingly, it is possible to simplify the structure and reduce the man-hours.
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FIG. 1 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a first embodiment of the invention. -
FIGS. 2A-2C are diagrams illustrating an input shaft (input-side rotating body) of a ball type speed reducer according to a first embodiment of the invention, in whichFIG. 2A is a front view illustrating the input shaft (view illustrating a leading end face),FIG. 2B is a side view illustrating the input shaft, andFIG. 2C is a view illustrating a trailing end face of the input shaft. -
FIGS. 3A-3C are diagrams illustrating a cap (input-side rotating body) of the ball type speed reducer according to the first embodiment of the invention, in whichFIG. 3A is a front view illustrating the cap,FIG. 3B is a cross-sectional view taken along the line A1-A1 ofFIG. 3A to illustrate the cap, andFIG. 3C is a rear view illustrating the cap. -
FIGS. 4A and 4B are diagrams illustrating a shaking body of the ball type speed reducer according to the first embodiment of the invention, in whichFIG. 4A is a front view illustrating the shaking body, andFIG. 4B is a cross-sectional view taken along the line A2-A2 ofFIG. 4A to illustrate the shaking body. -
FIGS. 5A and 5B are diagrams illustrating a fixing member of the ball type speed reducer according to the first embodiment of the invention, in whichFIG. 5A is a front view illustrating the fixing member, andFIG. 5B is a cross-sectional view taken along the line A3-A3 ofFIG. 5A to illustrate the fixing member. -
FIGS. 6A and 6B are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the first embodiment of the invention, in whichFIG. 6A is a front view illustrating the first output-side rotating body, andFIG. 6B is a cross-sectional view taken along the line A4-A4 ofFIG. 6A to illustrate the first output-side rotating body. -
FIGS. 7A and 7B are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the first embodiment of the invention, in whichFIG. 7A is a front view illustrating the second output-side rotating body, andFIG. 7B is a cross-sectional view taken along the line A5-A5 ofFIG. 7A to illustrate the second output-side rotating body. -
FIG. 8 is a perspective view illustrating a corrugated groove of the ball type speed reducer according to the first embodiment of the invention in a simplified manner. -
FIGS. 9A and 9B are diagrams illustrating a rolling trajectory of a ball when the ball is rolled in the corrugated groove, in whichFIG. 9A is a plan view of the rolling trajectory of the ball, andFIG. 9B is a diagram illustrating waves whose rolling trajectory is projected on a virtual cross section taken along the line A6-A6 ofFIG. 9A . -
FIGS. 10A and 10B illustrate an explanatory diagram of a first modification of the corrugated groove inFIG. 10A , and an explanatory diagram of a second modification of the corrugated groove inFIG. 10B . -
FIG. 11 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a second embodiment of the invention. -
FIGS. 12A and 12B illustrate a front view of the first output-side rotating body inFIG. 12A , and a cross-sectional view taken along the line A7-A7 ofFIG. 12A to illustrate the first output-side rotating body inFIG. 12B . -
FIGS. 13A and 13B illustrate a front view of the second output-side rotating body inFIG. 13A , and a cross-sectional view taken along the line A8-A8 ofFIG. 13A to illustrate the second output-side rotating body inFIG. 13B . -
FIG. 14 is a longitudinal cross-sectional view illustrating a ball type speed reducer according to a third embodiment of the invention. -
FIG. 15 is a front view illustrating the ball type speed reducer according to the third embodiment of the invention in which a cap and a second output-side rotating body are removed. -
FIGS. 16A-16C are diagrams illustrating an input shaft (input-side rotating body) of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 16A is a front view illustrating the input shaft (view illustrating a leading end face),FIG. 16B is a side view illustrating the input shaft, andFIG. 16C is a cross-sectional view taken along the line A9-A9 ofFIG. 16A . -
FIGS. 17A-17C are diagrams illustrating a cap (input-side rotating body) of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 17A is a front view illustrating the cap,FIG. 17B is a side view illustrating the cap, andFIG. 17C is a cross-sectional view taken along the line A10-A10 ofFIG. 17A to illustrate the cap. -
FIGS. 18A and 18B are diagrams illustrating a shaking body of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 18A is a front view illustrating the shaking body, andFIG. 18A is a cross-sectional view taken along the line A11-A11 ofFIG. 18A to illustrate the shaking body. -
FIGS. 19A and 19B are diagrams illustrating a fixing member of the ball type speed reducer according to the third embodiment of the invention, in which FIG. 19A is a front view illustrating the fixing member, andFIG. 19B is a cross-sectional view taken along the line A12-A12 ofFIG. 19A to illustrate the fixing member. -
FIGS. 20A-20C are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 20A is a front view illustrating the first output-side rotating body,FIG. 20B is a side view illustrating the first output-side rotating body, andFIG. 20C is a cross-sectional view taken along the line A13-A13 ofFIG. 20A to illustrate the first output-side rotating body. -
FIGS. 21A-21C are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 21A is a front view illustrating the second output-side rotating body,FIG. 21B is a side view illustrating the second output-side rotating body, andFIG. 21C is a cross-sectional view taken along the line A14-A14 ofFIG. 21A to illustrate the second output-side rotating body. -
FIGS. 22A-22C are diagrams illustrating a rolling trajectory of a ball when the ball is rolled in a corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 22A is a plan view illustrating the rolling trajectory of the ball,FIG. 22B is a diagram illustrating waves whose rolling trajectory is projected on a virtual cross section taken along the line A15-A15 ofFIG. 22A , andFIG. 22C is an enlarged view illustrating the rolling trajectory of the ball ofFIG. 22B . -
FIGS. 23A and 23B are diagrams illustrating a feature of the corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 23A illustrates an arrangement in which balls are located at the top in a rolling trajectory of the ball, andFIG. 23B is a cylindrical cross-sectional view taken at the position corresponding to the line A16-A16 ofFIG. 23B to illustrate the ball type speed reducer. -
FIGS. 24A and 24B are diagrams illustrating a feature of the corrugated groove of the ball type speed reducer according to the third embodiment of the invention, in whichFIG. 24A illustrates an arrangement in which balls are located at a middle position between the top and the bottom in a rolling trajectory of the ball, andFIG. 24B is a cylindrical cross-sectional view taken at the position corresponding to the line A17-A17 ofFIG. 24A to illustrate the ball type speed reducer. -
FIGS. 25A and 25B illustrate a diagram (corresponding toFIG. 22C ) illustrating a rolling trajectory of a ball according to a first modification of the third embodiment of the invention inFIG. 25A , and a diagram (corresponding toFIG. 22C ) illustrating a rolling trajectory of a ball according to a second modification of the third embodiment of the invention inFIG. 25A . -
FIGS. 26A and 26B are diagrams illustrating a ball type speed reducer according to a fourth embodiment of the invention, in whichFIG. 26A is a front view illustrating the ball type speed reducer, andFIG. 26B is a side view illustrating the ball type speed reducer. -
FIG. 27 is a cross-sectional view taken along the line A18-A18 ofFIG. 26A to illustrate the ball type speed reducer. -
FIG. 28 is a front view illustrating the ball type speed reducer according to the fourth embodiment of the invention in which a cap and a second output-side rotating body are removed. -
FIGS. 29A-29D are diagrams illustrating an input shaft (input-side rotating body) of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 29A is a front view illustrating the input shaft (view illustrating a leading end face),FIG. 29B is a side view illustrating the input shaft,FIG. 29C is a rear view illustrating the input shaft (view illustrating a trailing end face), andFIG. 29D is a cross-sectional view taken along the line A19-A19 ofFIG. 29A . -
FIGS. 30A-30D are diagrams illustrating the cap (input-side rotating body) of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 30A is a front view illustrating the cap,FIG. 30B is a side view illustrating the cap,FIG. 30C is a rear view illustrating the cap, andFIG. 30D is a cross-sectional view taken along the line A20-A20 ofFIG. 30A to illustrate the cap. -
FIGS. 31A-31F are diagrams illustrating a modification of a shaking body of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 31A is a front view illustrating the shaking body,FIG. 31B is a side view illustrating the shaking body,FIG. 31C is a rear view illustrating the shaking body,FIG. 31D is a cross-sectional view taken along the line A21-A21 ofFIG. 31A to illustrate the shaking body,FIG. 31E is an enlarged view illustrating the section B1 ofFIG. 31B , andFIG. 31F is a diagram illustrating the shaking body engaging a ball. -
FIGS. 32A-32F are diagrams illustrating a fixing member of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 32A is a front view illustrating the fixing member,FIG. 32B is a side view illustrating the fixing member,FIG. 32C is a rear view illustrating the fixing member,FIG. 32D is a cross-sectional view taken along the line A22-A22 ofFIG. 32A to illustrate the fixing member,FIG. 32E is an enlarged view illustrating the section B2 ofFIG. 32A , andFIG. 32F is a cross-sectional view taken along the line A23-A23 ofFIG. 32E . -
FIGS. 33A-33D are diagrams illustrating a first output-side rotating body of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 33A is a front view illustrating the first output-side rotating body in which a corrugated groove is formed,FIG. 33B is a side view illustrating the first output-side rotating body,FIG. 33C is a cross-sectional view taken along the line A24-A24 ofFIG. 33A to illustrate the first output-side rotating body, andFIG. 33D is a rear view illustrating the first output-side rotating body. -
FIGS. 34A-34D are diagrams illustrating a second output-side rotating body of the ball type speed reducer according to the fourth embodiment of the invention, in whichFIG. 34A is a front view illustrating the second output-side rotating body in which a corrugated groove is formed,FIG. 34B is a side view illustrating the second output-side rotating body,FIG. 34C is a cross-sectional view taken along the line A25-A25 ofFIG. 34A to illustrate the second output-side rotating body, andFIG. 34D is a rear view illustrating the second output-side rotating body. -
FIGS. 35A and 35B are diagrams illustrating a ball type speed reducer of the prior art, in whichFIG. 35A is a longitudinal cross-sectional view illustrating the ball type speed reducer, andFIG. 35B is a cross-sectional view taken along the line A26-A26 ofFIG. 35A . - Embodiments of the present invention will now be described with reference to the accompanying drawings.
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FIG. 1 is a longitudinal cross-sectional view illustrating a balltype speed reducer 1 according to a first embodiment of the invention. As illustrated inFIG. 1 , the balltype speed reducer 1 according to this embodiment includes an input shaft (input-side rotating body) 2, a cap (input-side rotating body) 3, aneccentric disk cam 4, a shakingbody 5, a plurality of balls (steel balls) 6, a fixingmember 7, an output-side rotating body 8 (a first output-siderotating body 8A and a second output-siderotating body 8B), and the like. - As illustrated in
FIGS. 1-2C , theinput shaft 2 turnably supports the first output-siderotating body 8A by interposing afirst bearing 10, so that theinput shaft 2 is rotationally driven by a motor or the like (not shown). Theinput shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of ashaft body portion 11 is adjacent to theshaft body portion 11. Abearing support portion 13 is formed adjacent to the flange-like portion 12. Thefirst bearing 10 is attached to thebearing support portion 13 to hold thefirst bearing 10 between aninner protrusion 15 of abearing hole 14 of the first output-siderotating body 8A and the flange-like portion 12. Further, theinput shaft 2 has theeccentric disk cam 4 formed closer to a shaft tip side than the bearingsupport portion 13 and in the vicinity of thebearing support portion 13. Thiseccentric disk cam 4 is a decentered shaft portion having acenter 4 a decentered from arotation center 2 a of the input shaft 2 (arotation center 11 a of the shaft body portion 11) by an eccentric amount “e,” and is eccentrically rotated integrally with theinput shaft 2 by virtue of rotation of therotation center 2 a of theinput shaft 2. In addition, the shakingbody 5 is relatively turnably installed in the outer circumference side of theeccentric disk cam 4 by interposing asecond bearing 16. Further, theinput shaft 2 has atip shaft portion 17 formed to install thecap 3. Thetip shaft portion 17 has a rotation center concentric with therotation center 2 a of theshaft body portion 2 and fitted in ashaft hole 18 of thecap 3 and has a leading end face 17 a abutting on astopper protrusion 20 protruding into theshaft hole 18 of thecap 3. Further, in thetip shaft portion 17 of theinput shaft 2, a screw hole (female screw) 22 to be screwed with ascrew shaft portion 21 a of abolt 21 for fixing thecap 3 is formed. Note that, in the following description, considering a virtual plane perpendicular to therotation center 2 a of theinput shaft 2, it is assumed that a radial direction refers to a direction extending radially from therotation center 2 a on the virtual plane. Further, considering the virtual plane perpendicular to therotation center 2 a of theinput shaft 2, it is assumed that a circumferential direction refers to a direction along an outer edge of a virtual circle centered at therotation center 2 a of theinput shaft 2. - As shown in
FIGS. 1 and 3A-3C , thecap 3 is fixed to thetip shaft portion 17 of theinput shaft 2 with thebolt 21, constitutes an input-side rotating body together with theinput shaft 2, and has arotation center 3 a coinciding with therotation center 2 a of theinput shaft 2. Thecap 3 has theshaft hole 18 opened at one end side (right end side inFIG. 3B ) along therotation center 3 a, a bolthead housing hole 23 opened at the other end side along therotation center 3 a (left end side inFIG. 3B ), and a boltshaft insertion hole 24 through which the bolthead housing hole 23 and theshaft hole 18 are communicated with each other. Further, thecap 3 has a ring-shapedbearing stopper 25 on one end side of a cylindrical outercircumferential surface 3 b. A side face of athird bearing 26 attached to the outercircumferential surface 3 b abuts on the bearingstopper 25, so that thethird bearing 26 is held between aninner protrusion 28 in abearing hole 27 of the second output-siderotating body 8B and the bearingstopper 25. Note that, in thecap 3, the rotation center of theshaft hole 18 and the rotation center of the outercircumferential surface 3 b are concentric with therotation center 3 a of thecap 3. - As shown in
FIGS. 1 and 4A-4B , the shakingbody 5 is formed in a disk shape so as to be shaken by theeccentric disk cam 4, has acentral bearing hole 30 fitted to the outer circumferential surface of thesecond bearing 16, and is supported by thesecond bearing 16 so as to be able to turn relative to theeccentric disk cam 4. In the shakingbody 5, acenter 5 a is formed so as to be concentric with thecenter 4 a of theeccentric disk cam 4, and an outer circumferential surface 5 b is a cylindrical surface concentric with thecenter 4 a of theeccentric disk cam 4. The plurality ofballs 6 are rotatably supported at the outer circumferential surface 5 b. Further, in the shakingbody 5, eight throughholes 31 are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearinghole 30. The throughhole 31 of the shakingbody 5 is engaged with acoupling protrusion 33 formed on a firstside face portion 32 of the first output-siderotating body 8A with a gap therebetween, and is formed to have a size such that the throughhole 31 does not contact thecoupling protrusion 33 even when the shakingbody 5 is shaken by theeccentric disk cam 4. - As shown in
FIGS. 1 and 5A-5B , the fixingmember 7 has a substantially square shape on the front side, and a shakingbody housing hole 34 is formed in its central portion. The fixingmember 7 has a fixingframe portion 35 formed along the outer edge, and a radial groove formingdisk portion 36 formed on the inner side of the radial direction of the fixingframe portion 35. In addition, in the fixingmember 7, bolt holes 37 are formed at four corners of the fixingframe portion 35. Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixingmember 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts. The fixingmember 7 is fixed to the fixation target member such that acenter 34 a of the shakingbody housing hole 34 is concentric with therotation center 2 a of theinput shaft 2. In addition, the shakingbody 5 is housed in the shakingbody housing hole 34 of the fixingmember 7 so as to be able to be shaken. Further, in the fixingmember 7, a plurality ofradial grooves 38 extending along the radial direction from an innercircumferential surface 34 b of the shakingbody housing hole 34 are formed along the circumferential direction at equal intervals (in “(N+1)/3” places when the number of waves of acorrugated groove 40 is set to “N”). Theradial groove 38 is an open end whose radial inner end allows theball 6 to enter and exit, has a groove width slightly larger than the diameter of theball 6, and has a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (the eccentric amount e of the eccentric disk cam 4), so that theball 6 supported at the outer circumferential surface 5 b of the shakingbody 5 is slidably moved along the radial direction. Further, in the fixingmember 7, a plate thickness of the radial groove formingdisk portion 36 is formed smaller than the diameter of theball 6, so that theball 6 is uniformly protruded on both sides of the radial groove formingdisk portion 36 and theball 6 in theradial groove 38 is rollably engaged with thecorrugated groove 40 formed in the output-siderotating body 8 when the center of theball 6 engaged with theradial groove 38 is aligned with the center position in the thickness direction of the radial groove formingdisk portion 36. Suchradial grooves 30 of the fixingmember 7 can roll theballs 6 in the radial direction depending on a shake amount of the shakingbody 5 as theeccentric disk cam 4 rotates by one turn, and the shakingbody 5 is shaken by one stroke. Note that, in this embodiment, the plate thickness of the radial groove formingdisk portion 36 of the fixingmember 7 is the same as the plate thickness of the shakingbody 5. - As shown in
FIGS. 1 and 6A-6B , the first output-siderotating body 8A has the firstside face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shakingbody 5, and one side face 36 a of both side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. Further, in the first output-siderotating body 8A, the bearinghole 14 for housing thefirst bearing 10 attached to theinput shaft 2 is formed, so that the side face of the outer race of thefirst bearing 10 abuts on theinner protrusion 15 formed at the end of the bearinghole 14. In the firstside face portion 32 of the first output-siderotating body 8A, a plurality ofcoupling protrusions 33 for coupling and fixing the second output-siderotating body 8B are formed at equal intervals (in eight places) in the circumferential direction. Thecoupling protrusion 33 is inserted into the throughhole 31 of the shakingbody 5 so as to be fitted in a couplingprotrusion housing recess 42 formed on a secondside face portion 41 of the second output-siderotating body 8B. In addition, in thecoupling protrusion 33, a screw hole (female screw) 44 for fixing the second output-siderotating body 8B with abolt 43 is formed. Further, in the firstside face portion 32 of the first output-siderotating body 8A, acontact relief recess 45 is formed between theadjacent coupling protrusions contact relief recess 45. Further, in the firstside face portion 32 of the first output-siderotating body 8A, thecorrugated groove 40 is formed on the outer side of the radial direction of thecoupling protrusion 33 and thecontact relief recess 45. - As shown in
FIGS. 1 and 7A-7B , the second output-siderotating body 8B has the secondside face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shakingbody 5, and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. In the secondside face portion 41 of the second output-siderotating body 8B, a plurality of the couplingprotrusion housing recesses 42 in which thecoupling protrusions 33 are fitted are formed as many as thecoupling protrusions 33 at positions facing therespective coupling protrusions 33 of the first output-siderotating body 8A. Further, in the secondside face portion 41 of the second output-siderotating body 8B, acontact relief recess 46 is formed between the adjacent couplingprotrusion housing recesses contact relief recess 46. Further, in the second output-siderotating body 8B, the bearinghole 27 for housing thethird bearing 26 attached to thecap 3 is formed, so that the side face of the outer race of thethird bearing 26 abuts on theinner protrusion 28 formed at the end of the bearinghole 27. Further, in the second output-siderotating body 8B, arelief hole 47 for avoiding contact with thesecond bearing 16 is formed on the inner side of the radial direction on the secondside face portion 41 side. Further, in the secondside face portion 41 of the second output-siderotating body 8B, thecorrugated groove 40 is formed on the outer side of the radial direction of the couplingprotrusion housing recess 42 and thecontact relief recess 46. Further, in the second output-siderotating body 8B, a bolthead housing recess 50 opened at aside face 48 placed opposite to the secondside face portion 41 is formed at a position facing thecoupling protrusion 33 of the first output-siderotating body 8A, and abolt hole 51 through which the bolthead housing recess 50 and the couplingprotrusion housing recess 42 are communicated with each other is formed. In addition, in the second output-siderotating body 8B, ascrew shaft portion 43 a of thebolt 43 inserted into the bolthead housing recess 50 and thebolt hole 51 is screwed into thescrew hole 44 of thecoupling protrusion 33 of the first output-siderotating body 8A, so that the second output-siderotating body 8B is fixed to the first output-siderotating body 8A, and is integrated with the first output-siderotating body 8A to constitute the output-siderotating body 8. Note that, in the second output-siderotating body 8B, a plurality of screw holes 52 are formed along the circumferential direction at a position radially inward of the bolthead housing recess 50 on theside face 48 opposite to the secondside face portion 41, so that a rotation target member (not shown) to be turned by the second output-siderotating body 8B is fixed with a plurality of bolts (not shown) screwed into the plurality of screw holes 52. - As shown in
FIGS. 1, 6A-6B, 7A-7B . and 8, thecorrugated groove 40 is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, and an even number (“N”=50) of waves are continuously formed annularly around therotation center 2 a of theinput shaft 2, so that thecorrugated groove 40 is rollably engaged with theballs 6 housed in theradial groove 38 of the fixing member in “(N+1)/3” places (17 places). When thecorrugated groove 40 is formed to have waves in which a portion located at a radial inner end of a wave is referred to as a bottom 40 a and a portion located at a radial outer end of the wave is referred to as a top 40 b, the bottom 40 a is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B. The top 40 b of odd-numbered waves is formed to have a groove depth such that any one side of the firstside face portion 32 and the secondside face portion 41 is deeper than the other side of the firstside face portion 32 and the secondside face portion 41, the top 40 b of even-numbered waves is formed to have a groove depth such that the other side of the firstside face portion 32 and the secondside face portion 41 is deeper than the one side of the firstside face portion 32 and the secondside face portion 41, and the groove depth is formed to gradually increase from the bottom 40 a toward the top 40 b. That is, thecorrugated groove 40 has a shape similar to “offset teeth” of a saw blade. When moving along the radial direction in theradial groove 38, theball 6, which is engaged with thecorrugated groove 40 of the first output-siderotating body 8A, thecorrugated groove 40 of the second output-siderotating body 8B, and also theradial groove 38 of the fixingmember 7, is also moved in the direction along therotation center 2 a of theinput shaft 2 by following the three-dimensionally formedcorrugated groove 40. Note that, although thecorrugated groove 40 is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B as described above, thecorrugated groove 40 is shaped with high precision without any deviation between thecorrugated groove 40 on the first output-siderotating body 8A side and thecorrugated groove 40 on the second output-siderotating body 8B side. This is because when the first output-siderotating body 8A and the second output-siderotating body 8B are fixed, the first output-siderotating body 8A and the second output-siderotating body 8B are in a state of being positioned with high accuracy by aligning apositioning groove 53 of the first output-siderotating body 8A with apositioning groove 54 of the second output-siderotating body 8B (seeFIGS. 1, 6A-6B, and 7A-7B ). -
FIGS. 9A and 9B are diagrams illustrating a rollingtrajectory 55 of theball 6 when theball 6 is rolled in thecorrugated groove 40. Note thatFIG. 9A is a plan view illustrating the rollingtrajectory 55 of the ball 6 (rollingtrajectory 55 projected on a virtual plane perpendicular to therotation center 2 a of the input shaft 2).FIG. 9B is a diagram illustrating waves W1 and W2 of adjacent rolling trajectories projected on a virtual cross section taken along the line A6-A6 ofFIG. 9A . In addition, the rollingtrajectory 55 of theball 6 shown inFIGS. 9A and 9B indicates a groove shape of thecorrugated groove 40. Further, inFIGS. 9A and 9B , R represents the radial direction, and Z represents the direction along therotation center 2 a of theinput shaft 2. - As shown in
FIGS. 9A and 9B , in the rollingtrajectory 55 of theball 6, the first wave W1 of the waves W1 and W2 of the rollingtrajectories 55 adjacent to each other is inclined from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the −Z direction at a constant rate. On the other hand, the second wave W2 of the rollingtrajectory 55 is inclined from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the +Z direction at a constant rate. In addition, the amount of movement of the first wave W1 in the −Z direction is the same as the amount of movement of the second wave W2 in the +Z direction. Note that, for example, thecorrugated groove 40 which forms the first wave W1 of the rollingtrajectory 55 is formed such that a portion corresponding to the top 40 b is deeper on the firstside face portion 32 side of the first output-siderotating body 8A. In contrast to the first wave W1, thecorrugated groove 40 which forms the second wave W2 of the rollingtrajectory 55 is formed such that a portion corresponding to the top 40 b is deeper on the secondside face portion 41 side of the second output-siderotating body 8B. -
FIG. 10A is a diagram illustrating a first modification of thecorrugated groove 40, and corresponding toFIG. 9B . In the rollingtrajectory 55 of theball 6 shown inFIG. 10A , the first wave W1 of the waves W1 and W2 of the rollingtrajectories 55 adjacent to each other has a moving rate increased from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the −Z direction (as theball 6 moves from radially inward to radially outward). On the other hand, the second wave W2 of the rollingtrajectory 55 has a moving rate increased from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the +Z direction (as theball 6 moves from radially inward to radially outward). Thecorrugated groove 40 may be formed to have the rollingtrajectory 55 of theball 6 shown inFIG. 10A . -
FIG. 10B is a diagram illustrating a second modification of thecorrugated groove 40, and corresponding toFIG. 9B . In the rollingtrajectory 55 of theball 6 shown inFIG. 10B , the first wave W1 of the waves W1 and W2 of the rollingtrajectories 55 adjacent to each other has a moving rate decreased from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the −Z direction (as theball 6 moves from radially inward to radially outward). On the other hand, the second wave W2 of the rollingtrajectory 55 has a moving rate decreased from the bottom 40 a to the top 40 b of thecorrugated groove 40 in the +Z direction (as theball 6 moves from radially inward to radially outward). Thecorrugated groove 40 may be formed to have the rollingtrajectory 55 of theball 6 shown inFIG. 10B . - In the ball
type speed reducer 1 according to this embodiment described above, as theinput shaft 2 and theeccentric disk cam 4 rotate integrally by one turn, the shakingbody 5 is shaken by a dimension “2e” twice the eccentric amount “e” of theeccentric disk cam 4, so that theballs 6 supported at the outer circumferential surface 5 b of the shakingbody 5 reciprocate inside theradial grooves 38 of the fixingmember 7 by one trip. In this case, the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B) turns with respect to the fixingmember 7 by one wave of thecorrugated groove 40 because theballs 6 move in the radial direction of the firstside face portion 32 and the secondside face portion 41 inside theradial grooves 38 of the fixingmember 7. Therefore, in the balltype speed reducer 1 according to this embodiment, since the number of waves of thecorrugated groove 40 is set to “N,” and the number ofradial grooves 38 is set to “(N+1)/3,” the output-siderotating body 8 rotates by a “1/N” turn oppositely to theinput shaft 2 while theinput shaft 2 rotates by one turn. Note that, as illustrated inFIGS. 5 and 8 , in the balltype speed reducer 1 according to this embodiment, the number “N” of waves of thecorrugated groove 40 of the output-siderotating body 8 is set to “50,” and the number “(N+1)/3” ofradial grooves 38 of the fixingmember 7 is set to “17” by way of example. Therefore, the balltype speed reducer 1 according to this embodiment decelerates rotation of theinput shaft 2 by “ 1/50 (1/N)” and transmits the decelerated rotation to the output-siderotating body 8. - In the ball
type speed reducer 1 according to this embodiment configured as described above, since thecorrugated grooves 40 are formed only in two places: the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, which face the shakingbody 5 and the fixingmember 7, it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (seeFIGS. 35A and 35B ) in which thecorrugated grooves type speed reducer 1 according to this embodiment, the shakingbody 5 can be shaken independently from the fixingmember 7 and the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B). Therefore, it is not necessary to provide a complicated mechanism for rotating the shakingbody 5 and the output-siderotating body 8 integrally (for example, theeccentricity absorption mechanism FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours. - In the ball
type speed reducer 1 according to this embodiment, theball 6 is positioned in a portion where theradial groove 38 and thecorrugated groove 40 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which theballs 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentricrotating plate 104 and the groove wall of the secondcorrugated groove 112 of the fixing member 107 (seeFIGS. 35A and 35B ), it is possible to facilitate machining of theradial groove 38 and thecorrugated groove 40 and an assembly work for the shakingbody 5, the fixingmember 7, the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B), and the like. - Further, in the ball
type speed reducer 1 according to this embodiment, compared to the case where thecorrugated groove 40 is formed to have an equal groove depth at the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, the groove depth at the top 40 b of thecorrugated groove 40 which contributes significantly to torque transmission is made deeper. Therefore, the amount of engagement between the top 40 b of thecorrugated groove 40 including its vicinity and theball 6 is increased, thereby making it possible to increase a transmittable torque. - Further, in the ball
type speed reducer 1 according to this embodiment, with respect to the number “N” of waves of thecorrugated groove 40, the number ofradial grooves 38 is set to “(N+1)/3” and the number ofballs 6 housed in theradial groove 38 is set to “(N+1)/3.” Therefore, it is possible to reduce the weight by the reduced number ofballs 6, compared to the case where the number ofradial grooves 38 is set to “(N+1)” and the number of balls housed in theradial groove 38 is set to “(N+1).” - Further, in the ball
type speed reducer 1 according to this embodiment, with respect to the number “N” of waves of thecorrugated groove 40, the number ofradial grooves 38 is set to “(N+1)/3” and the number ofballs 6 housed in theradial groove 38 is set to “(N+1)/3.” Therefore, the size of theball 6 can be set to be larger, and a large torque can be transmitted although the number ofballs 6 is reduced. - Further, in the ball
type speed reducer 1 according to this embodiment, since a plurality of the contact relief recesses 45 and 46 for reducing a contact resistance by reducing a contact area with the shakingbody 5 are provided in the first output-siderotating body 8A and the second output-siderotating body 8B, it is possible to effectively transmit power. Note that, in the balltype speed reducer 1 according to this embodiment, since a viscous resistance of the grease applied between the first output-siderotating body 8A and the second output-siderotating body 8B and the shakingbody 5 can be reduced by filling grease inside thecontact relief recess 45 of the first output-siderotating body 8A and thecontact relief recess 46 of the second output-siderotating body 8B, it is possible to reduce an energy loss caused by the viscous resistance of the grease and effectively transmit power. - Further, in the ball
type speed reducer 1 according to this embodiment, if the number of waves of thecorrugated groove 40 of the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B) is set to “N,” the reduction ratio becomes “1/N.” Therefore, it is possible to increase the reduction ratio relative to the ball type speed reducer 100 of the prior art illustrated inFIG. 35 . - In the ball
type speed reducer 1 according to this embodiment, the number “N” of waves of thecorrugated groove 40 of the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B) is set to “50,” the number “(N+1)/3” ofradial grooves 38 of the fixingmember 7 is set to “17,” and the number ofballs 5 is set to “17” by way of example. However, without limiting thereto, the number “N” of waves of thecorrugated groove 40, the number “(N+1)/3” ofradial grooves 38, and the number ofballs 6 may be determined to change the reduction ratio on the conditions that the number “N” of waves of thecorrugated groove 40 is set to an even number (a multiple of “2”) and the number “(N+1)/3” ofradial grooves 38 is set to a natural number. Note that the number ofballs 6 may be smaller than the number of grooves of theradial groove 40 as long as smooth rotation transmission of the balltype speed reducer 1 is not impaired. - Further, in the ball
type speed reducer 1 according to this embodiment, the number “N” of waves of thecorrugated groove 40 of the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B) is set to “50,” the number “(N+1)/3” ofradial grooves 38 of the fixingmember 7 is set to “17,” and the number ofballs 6 is set to “17” by way of example. However, without limiting thereto, the number “N” of waves of thecorrugated groove 40, the number “(N−1)/3” ofradial grooves 38, and the number ofballs 6 may be determined to change the reduction ratio on the conditions that the number “N” of waves of thecorrugated groove 40 is set to an even number (a multiple of “2”) and the number “(N−1)/3” ofradial grooves 38 is set to a natural number. For example, their numbers may be determined such that the number “N” of waves of thecorrugated groove 40 of the output-siderotating body 8 is set to “46,” the number “(N−1)/3” ofradial grooves 38 of the fixingmember 7 is set to “15,” and the number “(N−1)/3” ofballs 6 is set to “15.” In the balltype speed reducer 1 according to the second modification, the output-siderotating body 8 rotates by “1/N” for one rotation of theinput shaft 2 in the same rotation direction as theinput shaft 2. Note that the number ofballs 6 may be smaller than the number ofradial grooves 38 as long as smooth rotation transmission of the balltype speed reducer 1 is not impaired. -
FIGS. 11-13B are explanatory diagrams of the balltype speed reducer 1 according to a second embodiment of the invention. Note thatFIG. 11 is a longitudinal cross-sectional view illustrating the balltype speed reducer 1 according to the second embodiment of the invention.FIG. 12A is a front view illustrating the first output-siderotating body 8A, andFIG. 12B is a cross-sectional view taken along the line A7-A7 ofFIG. 12A to illustrate the first output-siderotating body 8A.FIG. 13A is a front view illustrating the second output-siderotating body 8B, andFIG. 13B is a cross-sectional view taken along the line A8-A8 ofFIG. 13A to illustrate the second output-siderotating body 8B. - As shown in
FIGS. 11-13B , in the balltype speed reducer 1 according to this embodiment, the shape ofcorrugated grooves 56 of the first output-siderotating body 8A and the second output-siderotating body 8B are different from the shape of thecorrugated grooves 40 of the first output-siderotating body 8A and the second output-siderotating body 8B in the balltype speed reducer 1 according to the first embodiment, but the other configuration is the same as the balltype speed reducer 1 according to the first embodiment. Therefore, in the description of the balltype speed reducer 1 according to this embodiment, like reference numerals denote like elements as in the balltype speed reducer 1 of the first embodiment, and they will not be repeatedly described. - In the ball
type speed reducer 1 according to this embodiment, thecorrugated groove 56 is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B. In addition, a firstcorrugated groove portion 56A on the first output-siderotating body 8A side and a secondcorrugated groove portion 56B on the second output-siderotating body 8B side in thecorrugated grooves 56 have the same planar shape and same groove depth, and has a shape such that one is mirrored to the other. Further, the firstcorrugated groove portion 56A on the first output-siderotating body 8A side and the secondcorrugated groove portion 56B on the second output-siderotating body 8B side are formed to have a constant groove depth, unlike thecorrugated grooves 40 of the balltype speed reducer 1 according to the first embodiment. Note that, in the balltype speed reducer 1 according to this embodiment, as in the balltype speed reducer 1 according to the first embodiment, the number of waves of the corrugated groove 56 (the numbers of waves of the firstcorrugated groove portion 56A of the first output-siderotating body 8A and the secondcorrugated groove portion 56B of the second output-siderotating body 8B) is set to “50,” the number “(N+1)/3” ofradial grooves 38 of the fixingmember 7 is set to “17,” and the number ofballs 6 is set to “17” by way of example. However, unlike the balltype speed reducer 1 according to the first embodiment, the balltype speed reducer 1 according to this embodiment is not limited to an even number “N” of waves of thecorrugated groove 56, and the number “N” of waves of thecorrugated groove 56 may be set to an odd number, and the number ofradial grooves 38 may be set to “N+1,” “N−1,” “(N+1)/2,” or “(N−1)/2.” - In the ball
type speed reducer 1 according to this embodiment configured as described above, since thecorrugated grooves 56 are formed only in two places: the firstside face portion 32 of the first output-siderotating body 8A and the second side face portion of the second output-siderotating body 8B (the firstcorrugated groove portion 56A of thecorrugated groove 56 is formed in the firstside face portion 32 of the first output-siderotating body 8A, and the secondcorrugated groove portion 56B of thecorrugated groove 56 is formed in the secondside face portion 41 of the second output-siderotating body 8B), it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (seeFIGS. 35A and 35B ) in which thecorrugated grooves type speed reducer 1 according to this embodiment, the shakingbody 5 can be shaken independently from the fixingmember 7 and the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B). Therefore, it is not necessary to provide a complicated mechanism for turning the shakingbody 5 and the output-siderotating body 8 integrally (for example, theeccentricity absorption mechanism FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours. - Further, in the ball
type speed reducer 1 according to this embodiment, theball 6 is positioned in a portion where theradial groove 38 and thecorrugated groove 56 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which theballs 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentricrotating plate 104 and the groove wall of the secondcorrugated groove 112 of the fixing member 107 (seeFIGS. 35A and 35B ), it is possible to facilitate machining of theradial groove 38 and thecorrugated groove 56 and an assembly work for the shakingbody 5, the fixingmember 7, the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B), and the like. -
FIG. 14 is a longitudinal cross-sectional view illustrating a balltype speed reducer 1 according to a third embodiment of the invention. As illustrated inFIG. 14 , the balltype speed reducer 1 according to this embodiment includes an input shaft (input-side rotating body) 2, a cap (input-side rotating body) 3, aneccentric disk cam 4, a shakingbody 5, a plurality of balls (steel balls) 6, a fixingmember 7, an output-side rotating body 8 (a first output-siderotating body 8A and a second output-siderotating body 8B), and the like.FIG. 15 is a front view illustrating the balltype speed reducer 1 in which thecap 3, the second output-siderotating body 8B, the shakingbody 5, and the like are removed. - As illustrated in
FIGS. 14-16C , theinput shaft 2 turnably supports the first output-siderotating body 8A by interposing afirst bearing 10, so that theinput shaft 2 is rotationally driven by a motor or the like (not shown). Theinput shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of ashaft body portion 11 is adjacent to theshaft body portion 11. Abearing support portion 13 is formed adjacent to the flange-like portion 12. Thefirst bearing 10 is attached to thebearing support portion 13 to hold thefirst bearing 10 between aninner protrusion 15 of abearing hole 14 of the first output-siderotating body 8A and the flange-like portion 12. Further, theinput shaft 2 has theeccentric disk cam 4 formed closer to a shaft tip side than the bearingsupport portion 13 and in the vicinity of thebearing support portion 13. Thiseccentric disk cam 4 is a decentered shaft portion having acenter 4 a decentered from arotation center 2 a of the input shaft 2 (arotation center 11 a of the shaft body portion 11) by an eccentric amount “e,” and is eccentrically rotated integrally with theinput shaft 2 by virtue of rotation of therotation center 2 a of theinput shaft 2. In addition, the shakingbody 5 is relatively turnably installed in the outer circumference side of theeccentric disk cam 4 by interposing asecond bearing 16. Further, theinput shaft 2 has atip shaft portion 17 formed to install thecap 3. Thetip shaft portion 17 has a rotation center concentric with therotation center 2 a of theshaft body portion 2 and fitted in ashaft hole 18 of thecap 3 and has a leading end face 17 a abutting on astopper protrusion 20 protruding into theshaft hole 18 of thecap 3. Further, in thetip shaft portion 17 of theinput shaft 2, a screw hole (female screw) 22 to be screwed with ascrew shaft portion 21 a of abolt 21 for fixing thecap 3 is formed. - As shown in
FIGS. 14 and 17A-17C , thecap 3 is fixed to thetip shaft portion 17 of theinput shaft 2 with thebolt 21, constitutes an input-side rotating body together with theinput shaft 2, and has arotation center 3 a coinciding with therotation center 2 a of theinput shaft 2. Thecap 3 has theshaft hole 18 opened at one end side (right end side inFIG. 17C ) along arotation center 3 a, a bolthead housing hole 23 opened at the other end side along therotation center 3 a (left end side inFIG. 17C ), and a boltshaft insertion hole 24 through which the bolthead housing hole 23 and theshaft hole 18 are communicated with each other. Further, thecap 3 has a ring-shapedbearing stopper 25 on the left end side of a cylindrical outercircumferential surface 3 b. A side face of athird bearing 26 attached to the outercircumferential surface 3 b abuts on the bearingstopper 25, so that thethird bearing 26 is held between aninner protrusion 28 in thebearing hole 27 of the second output-siderotating body 8B and the bearingstopper 25. Note that, in thecap 3, the rotation center of theshaft hole 18 and the rotation center of the outercircumferential surface 3 b are concentric with therotation center 3 a of thecap 3. Further, thecap 3 is formed to have an outer diameter of the outercircumferential surface 3 b that is the same as the outer diameter of thebearing support portion 13 of theinput shaft 2. In addition, thethird bearing 26 attached to the outercircumferential surface 3 b of thecap 3 as used is the same as thefirst bearing 10 attached to thebearing support portion 13 of theinput shaft 2. - As shown in
FIGS. 14 and 18A-18B , the shakingbody 5 is formed in a disk shape so as to be shaken by theeccentric disk cam 4, has acentral bearing hole 30 fitted to the outer circumferential surface of thesecond bearing 16, and is supported by thesecond bearing 16 so as to be able to turn relative to theeccentric disk cam 4. In the shakingbody 5, acenter 5 a is formed so as to be concentric with thecenter 4 a of theeccentric disk cam 4, and an outer circumferential surface 5 b is a cylindrical surface concentric with thecenter 4 a of theeccentric disk cam 4. The plurality ofballs 6 are rotatably supported at the outer circumferential surface 5 b. Further, in the shakingbody 5, four first throughholes 31 a are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearinghole 30. The first throughhole 31 a of the shakingbody 5 is engaged with acoupling protrusion 33 a formed on a firstside face portion 32 of the first output-siderotating body 8A with a gap therebetween, and is formed to have a size such that the first throughhole 31 a does not contact thecoupling protrusion 33 a even when the shakingbody 5 is shaken by theeccentric disk cam 4. Further, in the shakingbody 5, four second throughholes 31 b are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearinghole 30. The second throughhole 31 b of the shakingbody 5 is engaged with acoupling protrusion 33 b formed on a secondside face portion 41 of the second output-siderotating body 8B with a gap therebetween, and is formed to have a size such that the second throughhole 31 b does not contact thecoupling protrusion 33 b even when the shakingbody 5 is shaken by theeccentric disk cam 4. In addition, the first throughholes 31 a and the second throughholes 31 b are alternately arranged at equal intervals. - As shown in
FIGS. 14, 15, and 19A-19B , the fixingmember 7 has a substantially square shape on the front side, and a shakingbody housing hole 34 is formed in its central portion. The fixingmember 7 has a fixingframe portion 35 formed along the outer edge, and a radial groove formingdisk portion 36 formed on the inner side of the radial direction of the fixingframe portion 35. In addition, in the fixingmember 7, bolt holes 37 are formed at four corners of the fixingframe portion 35. Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixingmember 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts. The fixingmember 7 is fixed to the fixation target member such that acenter 34 a of the shakingbody housing hole 34 is concentric with therotation center 2 a of theinput shaft 2. In addition, the shakingbody 5 is housed in the shakingbody housing hole 34 of the fixingmember 7 so as to be able to be shaken. Further, in the fixingmember 7, a plurality ofradial grooves 38 extending along the radial direction from an innercircumferential surface 34 b of the shakingbody housing hole 34 are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of acorrugated groove 60 is set to “N”). Theradial groove 38 is an open end whose radial inner end allows theball 6 to enter and exit, has a groove width slightly larger than the diameter of theball 6, and has a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (the eccentric amount e of the eccentric disk cam 4), so that theball 6 supported at the outer circumferential surface 5 b of the shakingbody 5 is slidably moved along the radial direction. Further, in the fixingmember 7, a plate thickness of the radial groove formingdisk portion 36 is formed smaller than the diameter of theball 6, so that theball 6 is uniformly protruded on both sides of the radial groove formingdisk portion 36 and theball 6 in theradial groove 38 is rollably engaged with thecorrugated groove 60 formed in the output-siderotating body 8 when the center of theball 6 engaged with theradial groove 38 is aligned with the center position in the thickness direction of the radial groove formingdisk portion 36. Suchradial grooves 30 of the fixingmember 7 can roll theballs 6 in the radial direction depending on a shake amount of the shakingbody 5 as theeccentric disk cam 4 rotates by one turn, and the shakingbody 5 is shaken by one stroke. Note that, in this embodiment, the plate thickness of the radial groove formingdisk portion 36 of the fixingmember 7 is the same as the plate thickness of a ball support portion 5 e placed on the radial outward end side of the shakingbody 5. - As shown in
FIGS. 14 and 20A-20C , the first output-siderotating body 8A has the firstside face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shakingbody 5, and one side face 36 a of both side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. Further, in the first output-siderotating body 8A, the bearinghole 14 for housing thefirst bearing 10 attached to theinput shaft 2 is formed, so that the side face of the outer race of thefirst bearing 10 abuts on theinner protrusion 15 formed at the end of the bearinghole 14. In the firstside face portion 32 of the first output-siderotating body 8A, a plurality ofcoupling protrusions 33 a for coupling and fixing the second output-siderotating body 8B are formed at equal intervals (in four places) in the circumferential direction. Thecoupling protrusion 33 a is inserted into the throughhole 31 a of the shakingbody 5 so as to be fitted in a couplingprotrusion housing recess 42 b formed on a secondside face portion 41 of the second output-siderotating body 8B. Further, in the firstside face portion 32 of the first output-siderotating body 8A, a plurality of couplingprotrusion housing recesses 42 a for coupling and fixing the second output-siderotating body 8B are formed at equal intervals (in four places) in the circumferential direction. Acoupling protrusion 33 b is formed extending through the throughhole 31 b of the shakingbody 5 on the secondside face portion 41 of the second output-siderotating body 8B so as to be fitted in the couplingprotrusion housing recess 42 a. Further, in the firstside face portion 32 of the first output-siderotating body 8A, thecorrugated groove 60 is formed on the outer side of the radial direction of thecoupling protrusion 33 a and the couplingprotrusion housing recess 42 a. Further, on the back face side of the first output-siderotating body 8A (face side placed opposite to the first side face portion 32), screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than thecoupling protrusion 33 a. Further, in the first output-siderotating body 8A, apositioning groove 53 for positioning and fixing the second output-siderotating body 8B with high accuracy is formed at one position on the radial outer end. Note that the structures of thecoupling protrusion 33 a and the couplingprotrusion housing recess 42 a, and the structure for fixing the second output-siderotating body 8B to the first output-siderotating body 8A with bolts (not shown) are the same as the structures of the balltype speed reducer 1 shown inFIGS. 1 and 11 . - As shown in
FIGS. 14 and 21A-21C , the second output-siderotating body 8B has the secondside face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shakingbody 5, and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. In the secondside face portion 41 of the second output-siderotating body 8B, a plurality of couplingprotrusion housing recesses 42 b in which thecoupling protrusions 33 are fitted are formed as many as thecoupling protrusions 33 a at positions facing therespective coupling protrusions 33 a of the first output-siderotating body 8A. Further, in the secondside face portion 41 of the second output-siderotating body 8B, a plurality ofcoupling protrusions 33 b fitted to the couplingprotrusion housing recesses 42 a are formed as many as the couplingprotrusion housing recesses 42 a at positions facing the respective couplingprotrusion housing recesses 42 a of the first output-siderotating body 8A. Further, in the second output-siderotating body 8B, the bearinghole 27 for housing thethird bearing 26 attached to thecap 3 is formed, so that the side face of the outer race of thethird bearing 26 abuts on theinner protrusion 28 formed at the end of the bearinghole 27. Further, in the secondside face portion 41 of the second output-siderotating body 8B, thecorrugated groove 60 is formed on the outer side of the radial direction of thecoupling protrusion 33 b and the couplingprotrusion housing recess 42 b. Further, on the back face side of the second output-siderotating body 8B (face side placed opposite to the second side face portion 41), screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than thecoupling protrusion 33 b. Further, in the second output-siderotating body 8B, apositioning groove 54 for positioning and fixing the first output-siderotating body 8A with high accuracy is formed in the position (one position of the radial outer end) corresponding to thepositioning groove 53 of the first output-siderotating body 8A. Such a second output-siderotating body 8B has a shape as the secondside face portion 41 is viewed in plan (a shape shown inFIG. 21A ) that is the same as the shape as the first output-siderotating body 8A is viewed in plan (FIG. 20A ). Further, the second output-siderotating body 8B has the same longitudinal sectional shape (the sectional shape shown inFIG. 20C ) as the longitudinal sectional shape of the first output-siderotating body 8A (the sectional shape shown inFIG. 21C ). Note that the structures of thecoupling protrusion 33 b and the couplingprotrusion housing recess 42 b, and the structure for fixing the second output-siderotating body 8B to the first output-siderotating body 8A with bolts (not shown) are the same as the structures of the balltype speed reducer 1 shown inFIGS. 1 and 11 . - As shown in
FIGS. 14, 20A-20C, and 21A-21C , thecorrugated groove 60 is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, and an even number (“N”=50) of waves are continuously formed annularly around therotation center 2 a of theinput shaft 2, so that thecorrugated groove 60 is rollably engaged with theballs 6 housed in theradial groove 38 of the fixing member in “(N+1)” places (51 places). When thecorrugated groove 60 is formed to have waves in which a portion located at a radial inner end of a wave is referred to as a bottom 60 a and a portion located at a radial outer end of the wave is referred to as a top 60 b, the bottom 60 a and the top 60 b are formed equally across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, so that the bottom 60 a and the top 60 b in the firstside face portion 32 and the secondside face portion 41 have the same groove depth. Further, as shown inFIG. 20A , thecorrugated groove 60 is formed such that in regard to the firstside face portion 32 of the first output-siderotating body 8A, the groove depth gradually decreases from the bottom 60 a on a center line 61 toward the top 60 b on the right and then gradually increases, and the groove depth gradually increases from the top 60 b toward the bottom 60 a on the right and then gradually decreases. Further, as shown inFIG. 21A , thecorrugated groove 60 is formed such that in regard to the secondside face portion 41 of the second output-siderotating body 8B facing the firstside face portion 32 of the first output-siderotating body 8A, the groove depth gradually increases from the bottom 60 a on the center line 61 toward the top 60 b on the left and then gradually decreases, and the groove depth gradually decreases from the top 60 b toward the bottom 60 a on the left and then gradually increases. That is, thecorrugated groove 60 formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B spirally guides theball 6 along the circumferential direction of the first output-siderotating body 8A and the second output-siderotating body 8B. Therefore, when moving along the radial direction in theradial groove 38, theball 6, which is engaged with thecorrugated groove 60 formed across the first output-siderotating body 8A and the second output-siderotating body 8B and also theradial groove 38 of the fixingmember 7, is also moved in the direction along therotation center 2 a of theinput shaft 2 by following the three-dimensionally formedcorrugated groove 60. Note that, although thecorrugated groove 60 is formed across the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B as described above, thecorrugated groove 60 is shaped with high precision without any deviation between thecorrugated groove 60 on the first output-siderotating body 8A side and thecorrugated groove 60 on the second output-siderotating body 8B side. This is because when the first output-siderotating body 8A and the second output-siderotating body 8B are fixed, the first output-siderotating body 8A and the second output-siderotating body 8B are in a state of being positioned with high accuracy by aligning apositioning groove 53 of the first output-siderotating body 8A with apositioning groove 54 of the second output-siderotating body 8B (seeFIGS. 14, 20A-20C, and 21A-21C ). Further, thecorrugated groove 60 has only to guide theball 6 in a right-handed spiral or a left-handed spiral along the circumferential direction of the first output-siderotating body 8A and the second output-siderotating body 8B. -
FIGS. 22A-22C illustrating a rollingtrajectory 62 of theball 6 when theball 6 is rolled in thecorrugated groove 60. Note thatFIG. 22A is a plan view illustrating the rollingtrajectory 62 of the ball 6 (rollingtrajectory 62 projected on a virtual plane perpendicular to therotation center 2 a of the input shaft 2). Further,FIG. 22B is a diagram illustrating adjacent waves W1 and W2 in the rollingtrajectory 62 projected on a virtual cross section taken along the line A15-A15 ofFIG. 22A . Further,FIG. 22C is an enlarged view illustrating the rolling trajectory of the ball ofFIG. 22B . In addition, the rollingtrajectory 62 of theball 6 shown inFIGS. 22A-22C indicates a groove shape of thecorrugated groove 60. Further, inFIGS. 22A-22C , R represents the radial direction, and Z represents the direction along therotation center 2 a of theinput shaft 2. - As shown in
FIGS. 22A-22C , the rollingtrajectory 62 of theball 6 moving along thecorrugated groove 60 traces an elliptical shape whose major axis is the R direction. The center of theball 6 is located in the middle between the firstside face portion 32 and the secondside face portion 41 at each of the bottom 60 a and the top 60 b of the corrugated groove 60 (a bottom 62 a and a top 62 b of the rolling trajectory 62). The amount of movement in the +Z direction is gradually increased from the bottom 62 a of the first wave W1 toward the top 62 b of the first wave W1 and then gradually decreased, and the amount of movement in the −Z direction is gradually increased from the top 62 b of the first wave W1 toward the bottom 62 a of the adjacent second wave W2 and then gradually decreased. In addition, in the rollingtrajectory 62 of theball 6, the amount of movement in the +Z direction is the same as the amount of movement in the −Z direction. Such a rollingtrajectory 62 of theball 6 is shaped by thecorrugated groove 60 formed across the first output-siderotating body 8A and the second output-siderotating body 8B. -
FIGS. 23A-24B are diagrams illustrating features of thecorrugated groove 60 of the balltype speed reducer 1 according to this embodiment. Note thatFIG. 23A illustrates an arrangement in whichballs 6 are located at the top 62 b in the rollingtrajectory 62 of the ball 6 (a partial plan view illustrating the rolling trajectory 62), andFIG. 23B is a cylindrical cross-sectional view taken at the position corresponding to the line A16-A16 ofFIG. 23A to illustrate the balltype speed reducer 1. Further,FIG. 24A illustrates an arrangement in whichballs 6 are located at a middle position between the top 62 b and the bottom 62 a in the rollingtrajectory 62 of the ball 6 (a partial plan view illustrating the rolling trajectory 62), andFIG. 24B is a cylindrical cross-sectional view taken at the position corresponding to the line A17-A17 ofFIG. 24A to illustrate the balltype speed reducer 1. - As shown in
FIGS. 23A and 23B , in the balltype speed reducer 1 according to this embodiment, the top 62 b of the rollingtrajectory 62 of theball 6 is positioned at one end of the major axis of theelliptical rolling trajectory 62 ofFIG. 22C . Thecorrugated groove 60 has the same groove depth at each of the first output-siderotating body 8A and the second output-siderotating body 8B (the groove depth from the firstside face portion 32 and the groove depth from the secondside face portion 41 are the same). At each of the first output-siderotating body 8A and the second output-siderotating body 8B, aridge portion 63 having the same ridge height h1 is formed between theadjacent balls type speed reducer 1 according to this embodiment, the cylindrical cross-sectional view at the bottom 62 a of the rollingtrajectory 62 of theball 6 is the same asFIG. 23B . - Further, as shown in
FIGS. 24A and 24B , in the balltype speed reducer 1 according to this embodiment, the middle position between the top 62 b and the bottom 62 a of the rollingtrajectory 62 of theball 6 corresponds to the position of the minor axis of theelliptical rolling trajectory 62 ofFIG. 22C . Thecorrugated groove 60 has the same groove depth at each of the first output-siderotating body 8A and the second output-siderotating body 8B (the groove depth from the firstside face portion 32 and the groove depth from the secondside face portion 41 are the same). At each of the first output-siderotating body 8A and the second output-siderotating body 8B, aridge portion 63 having the same ridge height h2 is formed between theadjacent balls - As shown in
FIGS. 23A-24B , in the balltype speed reducer 1 according to this embodiment, since thecorrugated groove 60 engaged with theball 6 is formed in a spiral shape in the first output-siderotating body 8A and the second output-siderotating body 8B (seeFIGS. 22A-22C ), theridge portion 63 having the sufficient ridge height h1 or h2 that can prevent ratcheting is formed between theadjacent balls corrugated groove 60, the middle position between the bottom 60 a and the top 60 b of thecorrugated groove 60, and the position of the top 60 b of thecorrugated groove 60. - In the ball
type speed reducer 1 according to this embodiment configured as described above, since thecorrugated grooves 60 are formed only in two places: the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (seeFIGS. 35A and 35B ) in which thecorrugated grooves type speed reducer 1 according to this embodiment, the shakingbody 5 can be shaken independently from the fixingmember 7 and the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B). Therefore, it is not necessary to provide a complicated mechanism for turning the shakingbody 5 and the output-siderotating body 8 integrally (for example, theeccentricity absorption mechanism FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours. - Further, in the ball
type speed reducer 1 according to this embodiment, theball 6 is positioned in a portion where theradial groove 38 and thecorrugated groove 60 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which theballs 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentricrotating plate 104 and the groove wall of the secondcorrugated groove 112 of the fixing member 107 (seeFIGS. 35A and 35B ), it is possible to facilitate machining of theradial groove 38 and thecorrugated groove 60 and an assembly work for the shakingbody 5, the fixingmember 7, the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B), and the like. - Further, as shown in
FIGS. 14, 20A-20C, and 21A-21C , in the balltype speed reducer 1 according to the this embodiment, the first output-siderotating body 8A and the second output-siderotating body 8B have the same shape, so that their parts (the first output-siderotating body 8A, the second output-siderotating body 8B, thefirst bearing 10, and the third bearing 26) can be made common, thereby making it possible to reduce the parts cost. The technical concept of the balltype speed reducer 1 according to this embodiment can be applied to the balltype speed reducer 1 according to the first embodiment and the balltype speed reducer 1 according to the second embodiment. That is, in the balltype speed reducer 1 according to the first embodiment, the first output-siderotating body 8A and the second output-siderotating body 8B have the same shape, so that their parts (the first output-siderotating body 8A, the second output-siderotating body 8B, thefirst bearing 10, and the third bearing 26) are made common, thereby making it possible to reduce the parts cost. Note that, in this case, for example, by rotating the position of thecorrugated groove 40 of the first output-siderotating body 8A according to the first embodiment shown inFIGS. 6A and 6B by an angle of ½ wave with respect to thepositioning groove 54, the first output-siderotating body 8A and the second output-siderotating body 8B can have the same shape. Further, in the balltype speed reducer 1 according to the second embodiment, the first output-siderotating body 8A and the second output-siderotating body 8B have the same shape, so that their parts (the first output-siderotating body 8A, the second output-siderotating body 8B, thefirst bearing 10, and the third bearing 26) are made common, thereby making it possible to reduce the parts cost. -
FIG. 25A is a diagram illustrating a first modification of the rollingtrajectory 62 of theball 6, and corresponding toFIG. 22C . The rollingtrajectory 62 of theball 6 shown inFIG. 25A is a pair ofarcs center line 65 extending along the Z-axis direction is taken as a symmetry axis and also a line symmetry shape in which acenter line 66 extending along the R direction is taken as a symmetry axis. Thecorrugated groove 60 of the balltype speed reducer 1 according to this embodiment may be formed to have the rollingtrajectory 62 of theball 6 shown inFIG. 25A . -
FIG. 25B is a diagram illustrating a second modification of the rollingtrajectory 62 of theball 6, and corresponding toFIG. 22C . The rollingtrajectory 62 of theball 6 shown inFIG. 25B is a pair of arc-like shapes facing each other to form a substantially elliptical shape in which both end sections of thearc 64 inFIG. 25A are replaced withstraight lines center line 65 extending along the Z-axis direction is taken as a symmetry axis and also a line symmetry shape in which acenter line 66 extending along the R direction is taken as a symmetry axis. Thecorrugated groove 60 of the balltype speed reducer 1 according to this embodiment may be formed to have the rollingtrajectory 62 of theball 6 shown inFIG. 25B . -
FIGS. 26A-27 are diagrams illustrating a balltype speed reducer 1 according to a fourth embodiment of the invention. Note thatFIG. 26A is a front view illustrating the balltype speed reducer 1, andFIG. 26B is a side view illustrating the balltype speed reducer 1.FIG. 27 is a cross-sectional view taken along the line A18-A18 ofFIG. 26A to illustrate the balltype speed reducer 1. - As illustrated in
FIGS. 26A-27 , the balltype speed reducer 1 according to this embodiment includes an input shaft (input-side rotating body) 2, a cap (input-side rotating body) 3, aneccentric disk cam 4, a shaking body 5 (afirst shaking body 5A and a second shaking body 5B), a plurality of balls (steel balls) 6, a fixingmember 7, an output-side rotating body 8 (a first output-siderotating body 8A and a second output-siderotating body 8B), and the like.FIG. 27 is a front view illustrating the balltype speed reducer 1 in which thecap 3, the second output-siderotating body 8B, and the like are removed. - As illustrated in
FIGS. 26A-29D , theinput shaft 2 turnably supports the first output-siderotating body 8A by interposing afirst bearing 10, so that theinput shaft 2 is rotationally driven by a motor or the like (not shown). Theinput shaft 2 is formed such that a flange-like portion 12 having a diameter larger than that of ashaft body portion 11 is adjacent to theshaft body portion 11. Abearing support portion 13 is formed adjacent to the flange-like portion 12. Thefirst bearing 10 is attached to thebearing support portion 13 to hold thefirst bearing 10 between aninner protrusion 15 of abearing hole 14 of the first output-siderotating body 8A and the flange-like portion 12. Further, theinput shaft 2 has theeccentric disk cam 4 formed closer to a shaft tip side than the bearingsupport portion 13 and in the vicinity of thebearing support portion 13. Thiseccentric disk cam 4 is a decentered shaft portion having acenter 4 a decentered from arotation center 2 a of the input shaft 2 (arotation center 11 a of the shaft body portion 11) by an eccentric amount “e,” and is eccentrically rotated integrally with theinput shaft 2 by virtue of rotation of therotation center 2 a of theinput shaft 2. In addition, the shakingbody 5 is relatively turnably installed in the outer circumference side of theeccentric disk cam 4 by interposing asecond bearing 16. Further, theinput shaft 2 has atip shaft portion 17 formed to install thecap 3. Thetip shaft portion 17 has a rotation center concentric with therotation center 2 a of theshaft body portion 2 and fitted in ashaft hole 18 of thecap 3 and has a leading end face 17 a abutting on astopper protrusion 20 protruding into theshaft hole 18 of thecap 3. Further, in thetip shaft portion 17 of theinput shaft 2, a screw hole (female screw) 22 to be screwed with ascrew shaft portion 21 a of abolt 21 for fixing thecap 3 is formed. - As shown in
FIGS. 26A-26B, 27, and 30A-30D , thecap 3 is fixed to thetip shaft portion 17 of theinput shaft 2 with thebolt 21, constitutes an input-side rotating body together with theinput shaft 2, and has arotation center 3 a coinciding with therotation center 2 a. Thecap 3 has theshaft hole 18 opened at one end side (right end side inFIG. 30D ) along arotation center 3 a, a bolthead housing hole 23 opened at the other end side along therotation center 3 a (left end side inFIG. 30D ), and a boltshaft insertion hole 24 through which the bolthead housing hole 23 and theshaft hole 18 are communicated with each other. Further, thecap 3 has a ring-shapedbearing stopper 25 on the left end side of a cylindrical outercircumferential surface 3 b. A side face of athird bearing 26 attached to the outercircumferential surface 3 b abuts on the bearingstopper 25, so that thethird bearing 26 is held between aninner protrusion 28 in thebearing hole 27 of the second output-siderotating body 8B and the bearingstopper 25. Note that, in thecap 3, the rotation center of theshaft hole 18 and the rotation center of the outercircumferential surface 3 b are concentric with therotation center 3 a of thecap 3. Further, thecap 3 is formed to have an outer diameter of the outercircumferential surface 3 b that is the same as the outer diameter of thebearing support portion 13 of theinput shaft 2. In addition, thethird bearing 26 attached to the outercircumferential surface 3 b of thecap 3 as used is the same as thefirst bearing 10 attached to thebearing support portion 13 of theinput shaft 2. Further, thecap 3 holds thesecond bearing 16 in a state where thesecond bearing 16 is positioned between abearing positioning step 3 c and a bearing positioning step 2 b of theinput shaft 2. - As shown in
FIGS. 27 and 31A-31F , the shakingbody 5 is obtained by combining thefirst shaking body 5A and the second shaking body 5B which are the same shape, back to back. The shakingbody 5 is bifurcated into afirst edge portion 5 f (an outer circumferential edge portion of thefirst shaking body 5A) and asecond edge portion 5 g (an outer circumferential edge portion of the second shaking body 5B) on the outer circumferential end side. Thefirst edge portion 5 f is slidably engaged with one side face side of the fixingmember 7, and thesecond edge portion 5 g is slidably engaged with the other side face side of the fixingmember 7. Thefirst shaking body 5A is formed in a disk shape so as to be shaken by theeccentric disk cam 4, has acentral bearing hole 30 fitted to the outer circumferential surface of thesecond bearing 16, and is supported by thesecond bearing 16 so as to be able to turn relative to theeccentric disk cam 4. In thefirst shaking body 5A, acenter 5 a is formed so as to be concentric with thecenter 4 a of theeccentric disk cam 4, and an outer circumferential surface 5 b is a cylindrical surface concentric with thecenter 4 a of theeccentric disk cam 4. The plurality ofballs 6 are rotatably supported at the outer circumferential surface 5 b. Further, in thefirst shaking body 5A, ten throughholes 31 are formed at equal intervals along the circumferential direction on an outer side of the radial direction of the bearinghole 30. The throughhole 31 of thefirst shaking body 5A is engaged with acoupling protrusion 33 a formed on a firstside face portion 32 of the first output-siderotating body 8A and acoupling protrusion 33 b formed on a secondside face portion 41 of the second output-siderotating body 8B with a gap therebetween, and is formed to have a size such that the second throughhole 31 b does not contact thecoupling protrusions first shaking body 5A is shaken by theeccentric disk cam 4. Further, the outer circumferential surface 5 b of thefirst edge portion 5 f of thefirst shaking body 5A has an arc-like cross-sectional shape that can come in line contact with the outer circumferential surface of the ball 5 (seeFIG. 31F ). Note that, since the second shaking body 5B has the same shape as thefirst shaking body 5A, the same parts as those of thefirst shaking body 5A will not be repeatedly described. - As shown in
FIGS. 26A-28 and 32A-32F , the fixingmember 7 has a substantially square shape on the front side, and a shakingbody housing hole 34 is formed in its central portion. The fixingmember 7 has a fixingframe portion 35 formed along the outer edge, and a radial groove formingdisk portion 36 formed on the inner side of the radial direction of the fixingframe portion 35. In addition, in the fixingmember 7, bolt holes 37 are formed at four corners of the fixingframe portion 35. Fixing bolts (not shown) are inserted into the bolt holes 37 in the four places, so that the fixingmember 7 is fixed to a fixation target member (not shown) (for example, a machine frame or a robot arm) by the fixing bolts. The fixingmember 7 is fixed to the fixation target member such that acenter 34 a of the shakingbody housing hole 34 is concentric with therotation center 2 a of theinput shaft 2. In addition, the shaking body 5 (thefirst shaking body 5A and the second shaking body 5B) is housed in the shakingbody housing hole 34 of the fixingmember 7 so as to be able to be shaken. Thefirst edge portion 5 f of the shaking body 5 (the outer circumferential edge portion of thefirst shaking body 5A) is disposed to face one side face 36 a of the fixingmember 7. Further, thesecond edge portion 5 g of the shaking body 5 (the outer circumferential edge portion of the second shaking body 5B) is disposed to face the other side face 36 b of the fixingmember 7. - On one side face 36 a of the radial groove forming
disk portion 36 of the fixingmember 7, a plurality of elongated hole-shaped firstradial grooves 68 extending along the radial direction are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of acorrugated groove 70 is set to “N”). Further, on the other side face 36 b of the radial groove formingdisk portion 36 of the fixingmember 7, a plurality of elongated hole-shaped secondradial grooves 71 extending along the radial direction are formed along the circumferential direction at equal intervals (in “(N+1)” places when the number of waves of thecorrugated groove 70 is set to “N”). In addition, the secondradial grooves 71 are formed at positions when the firstradial grooves 68 are deviated by a half pitch in the circumferential direction (an angle of θ/2 where θ is the angle between the adjacent firstradial grooves 68, 68) so that the firstradial grooves 68 are turned upside down, and are also formed at the same positions in the radial direction as the firstradial grooves 68. The firstradial groove 68 and the secondradial groove 71 are formed such that their groove depth is smaller than the radius of theball 6 and their groove shape has an arc shape with the same radius as the radius of theball 6, and are also formed in line contact with theballs 6. Further, the firstradial groove 68 and the secondradial groove 71 are formed to have a groove length (length in the radial direction) which is a length taking into consideration the amount of shaking of the shaking body 5 (an eccentric amount “e” of the eccentric disk cam 4), so that theball 6 supported at the outer circumferential surface 5 b of the shakingbody 5 is slidably moved along the radial direction. Further, theball 6 housed in the firstradial groove 68 is rollably engaged with thecorrugated groove 70 of the first output-siderotating body 8A. Further, theball 6 housed in the secondradial groove 71 is rollably engaged with thecorrugated groove 70 of the second output-siderotating body 8B. Such firstradial grooves 68 and secondradial grooves 71 of the fixingmember 7 can roll theballs 6 in the radial direction depending on a shake amount of the shakingbody 5 as theeccentric disk cam 4 rotates by one turn, and the shakingbody 5 is shaken by one stroke. - In the fixing
member 7 configured as described above, the firstradial groove 68 formed on one side face 36 a of the radial groove formingdisk portion 36 and the secondradial groove 71 formed on the other side face 36 b are deviated from each other in the circumferential direction by a half pitch (angle of θ/2). Therefore, compared to the case where the firstradial groove 68 and the secondradial groove 71 are formed at the same position in the circumferential direction (the case where they are not deviated from each other in the circumferential direction), the thickness of the radial groove formingdisk portion 36 can be sufficiently secured, and the strength of the radial groove formingdisk portion 36 can be increased. Further, in the fixingmember 7, the firstradial groove 68 formed on one side face 36 a and the secondradial groove 71 formed on the other side face 36 b are deviated from each other in the circumferential direction by a half pitch. Therefore, compared to the case where the firstradial groove 68 and the secondradial groove 71 are formed at the same position in the circumferential direction (the case where they are not deviated from each other in the circumferential direction), the thickness of the radial groove formingdisk portion 36 can be reduced while the strength of the radial groove formingdisk portion 36 is maintained constant, thereby making it possible to achieve a light weight. - As shown in
FIGS. 26A-27, and 33A-33D , the first output-siderotating body 8A has the firstside face portion 32 placed to face one side face 5 c of both side faces 5 c and 5 d of the shakingbody 5, and one side face 36 a of both side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. Further, in the first output-siderotating body 8A, the bearinghole 14 for housing thefirst bearing 10 attached to theinput shaft 2 is formed, so that the side face of the outer race of thefirst bearing 10 abuts on theinner protrusion 15 formed at the end of the bearinghole 14. In the firstside face portion 32 of the first output-siderotating body 8A, a plurality ofcoupling protrusions 33 a for coupling and fixing the second output-siderotating body 8B are formed at equal intervals (in five places) in the circumferential direction. Thecoupling protrusion 33 a is inserted into the throughhole 31 of the shakingbody 5 so as to be fitted in a couplingprotrusion housing recess 42 b formed on a secondside face portion 41 of the second output-siderotating body 8B. Further, in the firstside face portion 32 of the first output-siderotating body 8A, a plurality of couplingprotrusion housing recesses 42 a for coupling and fixing the second output-siderotating body 8B are formed at equal intervals (in five places) in the circumferential direction. Acoupling protrusion 33 b is formed extending through the throughhole 31 of the shakingbody 5 on the secondside face portion 41 of the second output-siderotating body 8B so as to be fitted in the couplingprotrusion housing recess 42 a. Thecoupling protrusion 33 a and the couplingprotrusion housing recess 42 a are alternately arranged at equal intervals around a center C1 of the first output-siderotating body 8A. Further, in the firstside face portion 32 of the first output-siderotating body 8A, thecorrugated groove 70 is formed on the outer side of the radial direction of thecoupling protrusion 33 a and the couplingprotrusion housing recess 42 a. As shown inFIG. 33A, 50 waves are continuously formed in thecorrugated groove 70. When the radial inner end of a wave is referred to as a bottom and the radial outer end of the wave is referred to as a top, thecorrugated groove 70 is formed such that the top of the wave is placed on acenter line 72 which passes through the center C1 of the first output-siderotating body 8A and is parallel to the x direction. In addition, one of thecoupling protrusions 33 a and one of the couplingprotrusion housing recesses 42 a located at a two-fold symmetrical position with the one of thecoupling protrusions 33 a are arranged on acenter line 74 which is deviated counterclockwise by a ¼ pitch (an angle of θ/4 where θ is the angle between the adjacent firstradial grooves 68, 68) of the firstradial groove 68 with respect to a center line 73 (center line passing through the center C1 of the first output-siderotating body 8A and parallel to the y direction) perpendicular to thecenter line 72. - Further, on the back face side of the first output-side
rotating body 8A (face side placed opposite to the first side face portion 32), screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than thecoupling protrusion 33 a. The screw holes 52 are formed at a pair of positions on thecenter line 74, and are formed at a pair of positions on acenter line 75 perpendicular to thecenter line 74. - Further, in the first
side face portion 32 of the first output-siderotating body 8A, the radial groove formingdisk portion 36 of the fixingmember 7, thefirst edge portion 5 f of the shakingbody 5, and thesecond edge portion 5 g of the shakingbody 5 are housed between the secondside face portion 41 of the second output-siderotating body 8B and a portion radially inward of the corrugated groove 70 (more precisely, a region which enables the shakingbody 5 to shake). On the other hand, in the firstside face portion 32 of the first output-siderotating body 8A, only the radial groove formingdisk portion 36 of the fixingmember 7 is housed between the secondside face portion 41 of the second output-siderotating body 8B and a portion radially outward of the corrugated groove 70 (more precisely, a region where the outer circumferential end of the shakingbody 5 does not reach). Therefore, in the firstside face portion 32 of the first output-siderotating body 8A, since thecorrugated groove 70 is formed such that the groove depth of the firstradial groove 68 formed on one side face 36 a of the fixingmember 7 is smaller than the radius of theball 6, the groove depth on the top side can be made larger than the radius of theball 6. As a result, the first output-siderotating body 8A can effectively prevent the ratcheting in the vicinity of the top of thecorrugated groove 70 where the largest rotational torque acts when the rotation of the balltype speed reducer 1 is transmitted. -
FIGS. 34A-34D are diagrams illustrating the second output-siderotating body 8B. The second output-siderotating body 8B shown inFIG. 34A is obtained in such a manner that the first output-siderotating body 8A is turned upside down around the center line (reversal reference center line) 72 ofFIG. 33A , then the first output-siderotating body 8A is rotated 180 degrees around thecenter line 73, and subsequently the first output-siderotating body 8A is rotated clockwise around the center C1 of the first output-siderotating body 8A by a half pitch of the second radial groove 71 (an angle of θ/2 where θ is the angle between the adjacentradial grooves 71, 71). The second output-siderotating body 8B as used has the same shape as the first output-side rotating body. The second output-siderotating body 8B has the secondside face portion 41 placed to face the other side face 5 d of both the side faces 5 c and 5 d of the shakingbody 5, and the other side face 36 b of both the side faces 36 a and 36 b of the radial groove formingdisk portion 36 of the fixingmember 7. In the secondside face portion 41 of the second output-siderotating body 8B, a plurality of couplingprotrusion housing recesses 42 b fitted to thecoupling protrusions 33 are formed as many as thecoupling protrusions 33 a at positions corresponding to therespective coupling protrusions 33 a of the first output-side rotating body 8 a. Further, in the secondside face portion 41 of the second output-siderotating body 8B, a plurality ofcoupling protrusions 33 b fitted to the couplingprotrusion housing recesses 42 a are formed as many as the couplingprotrusion housing recesses 42 a at positions corresponding to the respective couplingprotrusion housing recesses 42 a of the first output-siderotating body 8A. Further, in the second output-siderotating body 8B, the bearinghole 27 for housing thethird bearing 26 attached to thecap 3 is formed, so that the side face of the outer race of thethird bearing 26 abuts on theinner protrusion 28 formed at the end of the bearinghole 27. Further, on the back face side of the second output-siderotating body 8B (face side placed opposite to the second side face portion 41), screw holes 52 for fixing a fixation target member are formed in four places at equal intervals along the circumferential direction closer to the inner side in the radial direction than thecoupling protrusion 33 b. - Further, in the second
side face portion 41 of the second output-siderotating body 8B, thecorrugated groove 70 is formed on the outer side of the radial direction of thecoupling protrusion 33 b and the couplingprotrusion housing recess 42 b. As shown inFIG. 34A, 50 waves are continuously formed in thecorrugated groove 70. Thecorrugated groove 70 is formed such that the top of the wave is placed on acenter line 76 rotated clockwise by θ/2 from thecenter line 72 which passes through the center C1 of the second output-siderotating body 8B and is parallel to the x direction. In addition, one of thecoupling protrusions 33 b and one of the couplingprotrusion housing recesses 42 b located at a two-fold symmetrical position with the one of thecoupling protrusions 33 b are arranged on thecenter line 74 perpendicular to thecenter line 75. - Note that the first output-side
rotating body 8A and the second output-siderotating body 8B are fixed in such a manner that a shaft portion 78 a of abolt 78 inserted into abolt hole 77 formed in the couplingprotrusion housing recess 42 b of the second output-siderotating body 8B is screwed into afemale screw portion 80 of thecoupling protrusion 33 a of the first output-siderotating body 8A; a shaft portion 78 a of abolt 78 inserted into abolt hole 77 formed in the couplingprotrusion housing recess 42 a of the first output-siderotating body 8A is screwed into afemale screw portion 80 of thecoupling protrusion 33 b of the second output-siderotating body 8B. - Further, in the second
side face portion 41 of the second output-siderotating body 8B, the radial groove formingdisk portion 36 of the fixingmember 7, thefirst edge portion 5 f of the shakingbody 5, and thesecond edge portion 5 g of the shakingbody 5 are housed between the firstside face portion 32 of the first output-siderotating body 8A and a portion radially inward of the corrugated groove 70 (more precisely, a region which enables the shakingbody 5 to shake). On the other hand, in the secondside face portion 41 of the second output-siderotating body 8B, only the radial groove formingdisk portion 36 of the fixingmember 7 is housed between the firstside face portion 32 of the first output-siderotating body 8A and a portion radially outward of the corrugated groove 70 (more precisely, a region where the outer circumferential end of the shakingbody 5 does not reach). Therefore, in the secondside face portion 41 of the second output-siderotating body 8B, since thecorrugated groove 70 is formed such that the groove depth of the secondradial groove 71 formed on the other side face 36 b of the fixingmember 7 is smaller than the radius of theball 6, the groove depth on the top side can be made larger than the radius of theball 6. As a result, the second output-siderotating body 8B can effectively prevent the ratcheting in the vicinity of the top of thecorrugated groove 70 where the largest rotational torque acts when the rotation of the balltype speed reducer 1 is transmitted. - As shown in
FIGS. 27 and 33A-34D , in the balltype speed reducer 1 according to this embodiment, when the first output-siderotating body 8A and the second output-siderotating body 8B are combined to be fixed, thecorrugated groove 70 of the first output-siderotating body 8A and thecorrugated groove 70 of the second output-siderotating body 8B are placed to be deviated from each other by a half pitch (θ/2) of the first radial groove 68 (or the second radial groove 71) in the circumferential direction. Therefore, even when the firstradial groove 68 and the secondradial groove 71 of the fixingmember 7 are formed to be deviated from each other by a half pitch (θ/2) in the circumferential direction, the positional relationship between the firstradial groove 68 of the fixingmember 7 and thecorrugated groove 70 of the first output-siderotating body 8A matches the positional relationship between the secondradial groove 71 of the fixingmember 7 and thecorrugated groove 70 of the second output-siderotating body 8B, thereby making it possible to achieve smooth rotation transmission. - In the ball
type speed reducer 1 according to this embodiment configured as described above, since thecorrugated grooves 70 are formed only in two places: the firstside face portion 32 of the first output-siderotating body 8A and the secondside face portion 41 of the second output-siderotating body 8B, it is possible to reduce the man-hours, compared to the ball type speed reducer 100 of the prior art (seeFIGS. 35A and 35B ) in which thecorrugated grooves type speed reducer 1 according to this embodiment, the shakingbody 5 can be shaken independently from the fixingmember 7 and the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B). Therefore, it is not necessary to provide a complicated mechanism for turning the shakingbody 5 and the output-siderotating body 8 integrally (for example, theeccentricity absorption mechanism FIGS. 35A and 35B ). Accordingly, it is possible to simplify the structure and reduce the man-hours. - Further, in the ball
type speed reducer 1 according to this embodiment, theballs 6 are positioned in a portion where the firstradial groove 68 and thecorrugated groove 70 intersect and in a portion where the secondradial groove 71 and thecorrugated groove 70 intersect. Therefore, compared to the ball type speed reducer 100 of the prior art in which theballs 108 simultaneously come into contact with the groove wall of the first corrugated groove 111 of the eccentricrotating plate 104 and the groove wall of the secondcorrugated groove 112 of the fixing member 107 (seeFIGS. 35A and 35B ), it is possible to facilitate machining of the firstradial groove 68, the secondradial groove 71, and thecorrugated groove 70, and an assembly work for the shakingbody 5, the fixingmember 7, the output-side rotating body 8 (the first output-siderotating body 8A and the second output-siderotating body 8B), and the like. - Further, in the ball
type speed reducer 1 according to the this embodiment, the first output-siderotating body 8A and the second output-siderotating body 8B have the same shape, so that their parts (the first output-siderotating body 8A, the second output-siderotating body 8B, thefirst bearing 10, and the third bearing 26) can be made common, thereby making it possible to reduce the parts cost. - Note that, in the ball
type speed reducer 1 according to this embodiment, the firstradial groove 68 and the secondradial groove 71 of the fixingmember 7 are formed to be deviated from each other by a half pitch (θ/2) along the circumferential direction. However, without limiting thereto, the firstradial groove 68 and the secondradial groove 71 of the fixingmember 7 may be formed at the same position in the circumferential direction. Note that, with such a configuration of the fixingmember 7, one of thecoupling protrusions 33 a of the first output-siderotating body 8A and one of the couplingprotrusion housing recesses 42 a located at a two-fold symmetrical position with the one of thecoupling protrusions 33 a are arranged on the center line 73 (the center line passing through the center C1 of the first output-siderotating body 8A and parallel to the y direction). - Further, in the ball
type speed reducer 1 according to this embodiment, the shakingbody 5 is obtained by combining thefirst shaking body 5A and the second shaking body 5B which are the same shape, back to back. However, without limiting thereto, the shakingbody 5 may be integrally formed as a whole. - In the ball
type speed reducers 1 according to the first to fourth embodiments of the invention, a ball bearing, a roller bearing, a bush or the like is used as the first tothird bearings - Further, in the ball
type speed reducers 1 of the first to fourth embodiments of the invention, the entire assembly of the speed reducer (including theinput shaft 2, thecap 3, the shakingbody 5, the fixingmember 7, the first output-siderotating body 8A, the second output-siderotating body 8B, and the like) may be formed of metal, a part of the assembly may be formed of a synthetic resin material, or the entire assembly except for the first tofourth bearings balls 6 may be formed of a synthetic resin material. In particular, in the balltype speed reducer 1 in which the entire assembly except for the first tothird bearings balls 6 is formed of a synthetic resin material, it is possible to reduce the weight and lower the product cost. Further, in the balltype speed reducer 1 in which the entire assembly except for the first tothird bearings balls 6 is formed of a synthetic resin material, it is possible to reduce a contact sound of the ball 6 (noise reduction) and suppress vibration. Furthermore, in the balltype speed reducers 1 according to the third and fourth embodiments, in the case where the entire assembly except for the first tothird bearings balls 6 is formed of a synthetic resin material, the first output-siderotating body 8A and the second output-siderotating body 8B can be made common, and accordingly one die is enough to injection molding, thereby making it possible to reduce the manufacturing cost. -
-
- 1 ball type speed reducer,
- 2 input shaft (input-side rotating body),
- 2 a rotation center,
- 3 cap (input-side rotating body),
- 4 eccentric disk cam,
- 4 a center,
- 5 shaking body,
- 5 b outer circumferential surface,
- 6 ball,
- 7 fixing member,
- 8 output-side rotating body,
- 8A first output-side rotating body
- 8B second output-side rotating body,
- 32 first side face portion,
- 38 radial groove,
- 40, 56, 60 corrugated groove,
- 40 a, 60 a bottom,
- 40 b, 60 b top,
- 41 second side face portion
Claims (10)
1. A ball type speed reducer that decelerates and transmits rotation of an input-side rotating body to an output-side rotating body, comprising:
an eccentric disk cam that turns integrally with the input-side rotating body;
a shaking body fitted relatively turnably to an outer circumference side of the eccentric disk cam and shaken by the eccentric disk cam;
a plurality of balls disposed along an outer circumferential surface of the shaking body;
a fixing member that houses the shaking body in an inner side of a radial direction such that the shaking body is shakable, the fixing member being fixed to a fixation target member;
a first output-side rotating body disposed to face one side face of the shaking body and the fixing member and relatively turnably supported by the input-side rotating body; and
a second output-side rotating body disposed to face the other side face of the shaking body and the fixing member and integrally turnably fixed to the first output-side rotating body, and relatively turnably supported by the input-side rotating body and constituting the output-side rotating body together with the first output-side rotating body,
wherein the outer circumferential surface of the shaking body is a cylindrical surface concentric with a center of the eccentric disk cam,
when a direction extending radially from a rotation center of the input-side rotating body is set as a radial direction on a virtual plane perpendicular to the rotation center, the fixing member has a plurality of radial grooves as many as the balls formed to slidably guide the balls in the radial direction, and radial inner ends of the radial grooves are open ends allowing the balls to enter and exit,
the first output-side rotating body has a first side face portion opposed to one side face of the fixing member,
the second output-side rotating body has a second side face portion opposed to the other side face of the fixing member, and
when a direction extending along an outer edge of a virtual circle centered at the rotation center on the virtual plane is set as a circumferential direction, the first side face portion and the second side face portion each have an annular corrugated groove formed to spirally guide the balls along the circumferential direction.
2. The ball type speed reducer according to claim 1 , wherein
the corrugated groove is formed to have an even number of waves continuously formed such that when a radial inner end of the wave is a bottom and a radial outer end of the wave is a top, the bottom is placed across the first side face portion and the second side face portion, the top of odd-numbered waves is formed to have a groove depth such that any one side of the first side face portion and the second side face portion is deeper than the other side of the first side face portion and the second side face portion, the top of even-numbered waves is formed to have a groove depth such that the other side of the first side face portion and the second side face portion is deeper than the one side of the first side face portion and the second side face portion, and the groove depth is formed to gradually increase from the bottom toward the top.
3. The ball type speed reducer according to claim 2 , wherein
when the number of waves of the corrugated groove is set to “N,” the number of grooves in the radial grooves is “(N+1)/3,” where “N” is an even number and “(N+1)/3” is a natural number.
4. The ball type speed reducer according to claim 2 , wherein
when the number of waves of the corrugated groove is set to “N,” the number of grooves in the radial grooves is “(N−1)/3,” where “N” is an even number and “(N−1)/3” is a natural number.
5. The ball type speed reducer according to claim 1 , wherein
the corrugated groove is formed to have waves such that when a radial inner end of the wave is a bottom and a radial outer end of the wave is a top, the first side face portion and the second side face portion at each of the bottom and the top have an equal groove depth, the groove depth of any one of the first side face portion and the second side face portion gradually increases from the bottom toward the top and then gradually decreases, the groove depth of the other one of the first side face portion and the second side face portion gradually decreases from the bottom toward the top and then gradually increases, the groove depth of the one of the first side face portion and the second side face portion gradually decreases from the top toward the bottom and then gradually increases, and the groove depth of the other one of the first side face portion and the second side face portion gradually increases from the top toward the bottom and then gradually decreases.
6. The ball type speed reducer according to claim 5 , wherein
a shape of the corrugated groove projected on a virtual cross section perpendicular to the virtual plane and including the rotation center of the input-side rotating body is an elliptical shape or a substantially elliptical shape.
7. A ball type speed reducer that decelerates and transmits rotation of an input-side rotating body to an output-side rotating body, comprising:
an eccentric disk cam that turns integrally with the input-side rotating body;
a shaking body fitted relatively turnably to an outer circumference side of the eccentric disk cam and shaken by the eccentric disk cam;
a plurality of balls disposed along an outer circumferential surface of the shaking body;
a fixing member that houses the shaking body in an inner side of a radial direction such that the shaking body is shakable, the fixing member being fixed to a fixation target member;
a first output-side rotating body disposed to face one side face of the shaking body and the fixing member and relatively turnably supported by the input-side rotating body; and
a second output-side rotating body disposed to face the other side face of the shaking body and the fixing member and integrally turnably fixed to the first output-side rotating body, and relatively turnably supported by the input-side rotating body and constituting the output-side rotating body together with the first output-side rotating body,
wherein the outer circumferential surface of the shaking body is a cylindrical surface concentric with a center of the eccentric disk cam,
when a direction extending radially from a rotation center of the input-side rotating body is set as a radial direction on a virtual plane perpendicular to the rotation center, the fixing member has a plurality of radial grooves as many as the balls formed at each of the one side face and the other side face to slidably guide the balls in the radial direction,
the first output-side rotating body has a first side face portion opposed to one side face of the fixing member,
the second output-side rotating body has a second side face portion opposed to the other side face of the fixing member, and
when a direction extending along an outer edge of a virtual circle centered at the rotation center on the virtual plane is set as a circumferential direction, the first side face portion and the second side face portion each have an annular corrugated groove formed to guide the balls along the circumferential direction.
8. The ball type speed reducer according to claim 7 , wherein
the ball housed in the radial groove formed on the one side face of the fixing member engages with the corrugated groove formed on the first side face portion of the first output-side rotating body,
the ball housed in the radial groove formed on the other side face of the fixing member engages with the corrugated groove formed on the second side face portion of the second output-side rotating body, and
when the corrugated groove has waves in which a radial inner end of the wave is a bottom and a radial outer end of the wave is a top, a groove depth of the top is larger than a radius of the ball.
9. The ball type speed reducer according to claim 7 , wherein
an outer circumferential end of the shaking body is bifurcated into a first end portion and a second end portion,
the first end portion is slidably engaged with the one side of the fixing member, and
the second end portion is slidably engaged with the other side of the fixing member.
10. The ball type speed reducer according to claim 8 , wherein
an outer circumferential end of the shaking body is bifurcated into a first end portion and a second end portion,
the first end portion is slidably engaged with the one side of the fixing member, and
the second end portion is slidably engaged with the other side of the fixing member.
Applications Claiming Priority (7)
Application Number | Priority Date | Filing Date | Title |
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JP2017-016770 | 2017-02-01 | ||
JP2017016770 | 2017-02-01 | ||
JP2017074304 | 2017-04-04 | ||
JP2017-074304 | 2017-04-04 | ||
JP2017159318A JP2018159466A (en) | 2017-02-01 | 2017-08-22 | Ball speed reducer |
JP2017-159318 | 2017-08-22 | ||
PCT/JP2018/000888 WO2018142909A1 (en) | 2017-02-01 | 2018-01-16 | Ball reduction gear |
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US16/482,472 Abandoned US20200011405A1 (en) | 2017-02-01 | 2018-01-16 | Ball type speed reducer |
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JP (1) | JP2018159466A (en) |
CN (1) | CN110249157A (en) |
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TWI663346B (en) * | 2018-08-27 | 2019-06-21 | 金洲科技有限公司 | Push-type transmission |
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JPH0762495B2 (en) * | 1985-06-27 | 1995-07-05 | 加茂精工株式会社 | Rolling ball type differential reduction mechanism |
IL94775A0 (en) * | 1989-06-21 | 1991-04-15 | Bollmann Dieter | Ball power gear unit |
JP3616804B2 (en) * | 2001-07-26 | 2005-02-02 | 伊東電機株式会社 | Roller with built-in motor with reduction gear, and reduction gear |
JP2009275739A (en) * | 2008-05-13 | 2009-11-26 | Nsk Ltd | Ball reduction gear |
WO2012033043A1 (en) * | 2010-09-09 | 2012-03-15 | Ntn株式会社 | Reduction device |
CN204099511U (en) * | 2014-09-19 | 2015-01-14 | 佛山市诺尔贝机器人技术有限公司 | A kind of power take-off mechanism of pendulum ball formula speed reducer |
-
2017
- 2017-08-22 JP JP2017159318A patent/JP2018159466A/en not_active Ceased
-
2018
- 2018-01-16 CN CN201880009572.2A patent/CN110249157A/en active Pending
- 2018-01-16 US US16/482,472 patent/US20200011405A1/en not_active Abandoned
- 2018-02-01 TW TW107103622A patent/TW201829937A/en unknown
Also Published As
Publication number | Publication date |
---|---|
TW201829937A (en) | 2018-08-16 |
JP2018159466A (en) | 2018-10-11 |
CN110249157A (en) | 2019-09-17 |
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